Methods and compositions of nucleic acid ligands for detection of clinical analytes related to human health

ABSTRACT

Specific DNA sequences for binding various clinically relevant analytes from the human body are described. Each of these sequences or their linear, two- and three-dimensional linked sequences can function in varying assay and sensor formats with varying degrees of success. Linkage of the whole or partial DNA sequences (putative binding sites) can be used to enhance specificity and affinity towards complex targets, thereby improving assay selectivity and sensitivity in many instances. In addition, a FRET-based quantitative method is described for normalizing analyte data by assessing urine creatinine and urea levels. Finally, a method is described for removing creatinine or urea by size-exclusion chromatography prior to a FRET-based aptamer assay to avoid the denaturing effects of these compounds.

PRIORITY INFORMATION

This application is based upon and claims priority from U.S. Provisionalapplication Ser. No. 61/402,491 filed on Aug. 31, 2010, and Ser. No.61/463,020 filed on Feb. 10, 2011, which are incorporated herein byreference.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention pertains to the field of aptamer- and nucleic acidligand (DNA and RNA ligand)-based diagnostics. More specifically, theapplication relates to single-stranded deoxyribonucleic acid (“DNA”) andribonucleic acid (“RNA”) ligand sequences, whether individual or linkedtogether to form longer multiple binding site “receptors,” thatspecifically target and bind to clinically relevant analytes on one ormore binding sites or “epitopes” from humans such a cardiovascularbiomarkers, bone metabolism markers, glucose, natural or recombinanthuman growth hormone (“hGH” or somatotropin) and vitamins. The inventionincludes general DNA ligand or aptamer-based detection and quantitationof these analytes in body fluids such as blood plasma, serum, sputum orsaliva, interstitial, synovial, or cerebrospinal fluid aspirates, mucus,and urine or solid biopsy samples.

2. Background Information

These individual or linked DNA ligand (aptamer) sequences representvaluable target analyte-responsive components of diagnostic devices orbiosensors. A “biosensor” is defined as any device that employs abiologically-derived molecule as the sensing component and transduces atarget analyte binding event into a detectable physical signal(including, but not limited to, changes in light intensity, absorbance,transmittance, refraction (Surface Plasmon Resonance or “SPR”),wavelength, color, agglutination of cells or particles, fluorescenceintensity, fluorescence lifetime, fluorescence polarization oranisotropy, fluorescence correlation spectroscopy (“FCS”), fluorescenceor Förster resonance energy transfer (“FRET”; nonradiative dipole-dipolecoupling of fluorophores or fluorophores and quenchers), upconvertingphosphor, two-photon interaction phenomena, Raman spectroscopy orsurface-enhanced Raman spectroscopy (“SERS”), electrical conduction,electrical resistance or other electrical properties, mass, photon orradioactive particle emissions, etc).

Once bonded with the target, these DNA ligand sequences can be used toqualitatively determine the presence of analyte, as well as to quantifyor semi-quantify the target analyte amount in a sample using a broadvariety of assay types and diagnostic or sensor platforms including, butnot limited to, affinity-based lateral flow test strips, membraneblotting, SPR, surface acoustic waveguides (“SAW” devices), magneticbead (“MB”)-based capture, plastic-adherent sandwich assays (“PASA”),chemiluminescence (“CL”), electrochemiluminescence (“ECL”),radioisotopic, fluorescence intensity, including quantum dot (“QD”) orother fluorescent nanoparticle (“FNP”) of dye-based, fluorescencelifetime, and fluorescence polarization (“FP”) assays or enzyme-linked(“ELISA-like”) microplate assays. ELISA-like assays refer to microwellor microplate assays similar to traditional Enzyme-Linked ImmunosorbentAssays (“ELISA”) in which an aptamer or nucleic acid ligand issubstituted for the antibody or receptor component or components, butthe other components such as peroxidase or alkaline phosphatase enzymesand color-producing substrates remain the same.

In addition, these DNA ligand sequences are valuable in competitivedisplacement assays which are not solely dependent on high affinity(strong attractive forces between a receptor and its ligand) or highavidity (high tensile or physical strength of receptor-ligand bonds) toproduce sensitive detection (sub-nanoMolar or sub-nanogram levels),because the equilibrium constant (generally K_(a)=10⁶ to 10⁸ to enablecompetition) must allow reasonable displacement of previously boundtarget materials to detect a change at or below nanogram or nanoMolarlevels.

In a competitive displacement assay, labeled DNA ligand plus labeledanalyte complexes compete with unlabeled analyte to bind with thelabeled DNA. After allowing the labeled and unlabeled analytes to cometo equilibrium with the labeled DNA, the unlabeled target analyte may bequantitatively assayed by fluorescence intensity or other methods. Suchassays would include competitive displacement FRET assays or DNA ligand“beacon” FRET assays. In a competitive displacement FRET assay thefluorophore (“F”) and quencher (“Q”) are placed in a putative bindingloop or pocket so as to reside within the Förster distance of 60-85Angstroms to enable quenching.

In an aptamer beacon assay, the F and Q labels are placed on the 5′ and3′ ends and binding of the target analyte to the beacon opens the beaconbeyond the Förster quenching distance so that F is no longer quenchedand emits light generally in proportion to the amount of target analyteintroduced into the liquid system. Each of these types of aptamer assaysand detection platforms has different applications in either centralmedical laboratories or in point-of-care (“POC”) sensor devices for usein emergency rooms, intensive care units, cardiac care units, orphysician's offices and clinics.

SUMMARY OF THE INVENTION

The DNA ligand sequences listed herein (Table 9) were derived byiterative cycles of affinity-based selection, washing, heated elution,and polymerase chain reaction (“PCR”) amplification of bound DNA ligandsfrom a randomized library using immobilized target analytes for affinityselection and PCR amplification followed by cloning and Sangerdideoxynucleotide DNA sequencing.

Sanger dideoxynucleotide sequencing refers to DNA chain termination dueto a lack of a 3′ hydroxyl (—OH) group to link incoming bases to duringDNA synthesis followed by automated fluorescence reading of the DNAsequence from an electrophoresis gel containing all of the terminatedDNA fragments. DNA sequencing may be accomplished by PCR doped withdideoxynucleotides lacking hydroxyl groups at the 2′ and 3′ sugar ringpositions and thereby disallowing chain formation. PCR refers to theenzymatic amplification or copying of DNA molecules with a thermo-stableDNA polymerase such as Thermus aquaticus polymerase (Taq) with known“primer” regions or short oligonucleotides of known sequence that canhybridize to a longer target DNA sequence to enable priming of the chainreaction (exponential doubling of the DNA target copy number with eachround of amplification).

A randomized library can be chemically synthesized by linking togetherthe four deoxynucleotide triphosphate bases (adenine; A, cytosine; C,guanine; G, and thymine; T) in equal amounts (25% each), so that acombinatorial oligonucleotide arises with sequence diversity equal to 4raised to the nth power (4^(n)) where n is the desired length of therandomized region in bases. In other words, if position 1 in anoligonucleotide is allowed to consist of A, C, G, or T (diversity=4) byequal availability of all 4 bases and these 4 possibilities aremultiplied by each base linking to 4 more possible bases at position 2,then this process yields 16 possible 2-base oligonucleotides (i.e., AA,AC, AG, AT, CA, CC, CG, CT, GA, GC, GG, GT, TA, TC, TG, TT) and so onfor the entire chosen length (n) of the randomized region. Thiscombinatorial progression displays immense diversity as a function ofoligonucleotide chain length. For 1,048,576 unique DNA sequences fromwhich to chose or select one or more DNA sequences that bind a givenimmobilized target analyte with the strongest affinities.

The randomized oligonucleotide or DNA is designed to be flanked oneither side by short primer regions of known and fixed sequences toenable PCR amplification (exponential copying) of the rare sequencesthat are selected from the random library by binding to the target afterthe non-binding members of the random library are washed away (notselected).

Additional assays, such as ELISA-like plate assays or fluorescence(e.g., intensity and FRET) assays, may be used to screen or verify thevalue of particular DNA and RNA ligands or aptamer sequences fordetection of a given target analyte in a given assay format or type ofbiosensor. Some of the sequences operate (bind and transduce the bindingsignal) more effectively in affinity-based (ELISA-like or fluorescenceintensity) assays, while other DNA ligand sequences against the sametargets function better in lower affinity competitive or other assays,thereby leading to more sensitive detection with lower limits ofdetection (sub-nanoMolar or sub-nanogram) and less cross-reactivity ormore specificity for the target analyte. “Specificity” or “selectivity”means the ability to selectively exclude molecules similar in structureto the true target analyte that may interfere with the assay and givefalse indications of detection. All of the listed DNA ligand nucleotidesequences have potential applications in some type of assay format,because they have survived at least 5 rounds of affinity-based selectionand enrichment (by PCR amplification), although some of the sequenceswill undoubtedly perform better in certain assay formats orconfigurations (in tubes, square cuvettes, membranes, or on biochips)than others.

Combinations of the DNA ligands, whether in whole or in part (i.e.,their binding sites of approximately 5-10 or more nucleotides or bases),could be linked together in a linear or 2-dimensional (“2-D”) or3-dimensional (“3-D”) fashion similar to dendrimers as shown in FIG. 1Bto bind multiple epitopes or binding sites on a complex target analyte(Ag or antigen) such as a virus or whole prokaryotic (bacterial) oreukaryotic (animal, fungal or plant) cell surface having numerousspatially separated epitopes of different types. The advantage oflinking aptamers or their shorter binding pockets, loops or bindingsites is that the nascent linear, 2-D, or 3-D aptamer construct willlikely have improved affinity or “avidity” (tensile binding strength)making it more difficult to remove or dissociate from the targetantigen. Higher affinity and avidity generally lead to greater assaysensitivity and specificity which are typically desirable traits in manyassays.

The linked aptamer complex will be likely to gain specificity as wellsince the probability of binding to multiple epitopes with any degree ofsuccess is multiplicative. Thus, the ability to bind to epitopes A, Band C equals the product of the probability of binding to A with highaffinity times the probability of binding to B with high affinity timesthe probability of binding to C with high affinity. The product of thosethree fractional probabilities is clearly much less than the probabilityof binding to only A, B, or C independently in the absence of bindingthe other two or any combination of the two epitopes therein in theabsence or binding the third. Hence by linking two or more aptamers ortheir binding regions with or without DNA or other “spacer” regions, theselectivity or specificity of aptamers or DNA ligands can be increased.

This approach to binding site linkage emulates the nature of antibodieswhich demonstrate linkage of their “hypervariable” (“HV”) regions on theantigen combining sites of the immunoglobulin (“Ig”) light and heavychains. In the HV regions, the variability of the 20 amino acid types isquite high and essentially represents a selection of one combinationfrom a large combinatorial library in the protein realm (similar to downselection of a few candidate aptamers from a large diverse startinglibrary). The trait of HV region linkage contributes to Ig affinity,avidity and specificity. Similarly, linking aptamers or aptamer bindingsites for various epitopes in one, two or three dimensions will enhancelarger aptamer or DNA ligand construct affinity, avidity, andselectivity or specificity as illustrated in FIG. 1.

The present invention provides specific DNA sequence information fornucleic acid ligands (aptamers) or their linked constructs selected fromrandomized pools to bind clinically important proteins, peptides,hormones, sugars, vitamins, post-translational N-acetylglucosamine (NAGor O-GlcNAc) modifications of key proteins, etc. in a variety of assayformats and sensor or diagnostic platforms for assessment of humanhealth status. While all of the candidate sequences have been shown tobind their cognate targets, some are shown to function more effectivelyin affinity-based assays versus fluorescence resonance energy transfer(FRET) or other assay formats that rely more on physical parametersother than affinity such as fluorophore-quencher proximity (i.e., theFörster distance). Therefore, all of the sequences are potentiallyvaluable for simple qualitative detection or quantitative assays, butsome may function better in terms of sensitive and specific detectionthan others in particular assay formats.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1A illustrates an antibody, revealing the multiple hypervariableantigen combining of binding sites on both the heavy and light chains.

FIG. 1B illustrates the concept of linking aptamers or their bindingsites in a linear fashion (although 2-D and 3-D linkages are alsopossible) to mimic the linkage of multiple hypervariable (HV) regions inantigen combining sites of antibody chains to enhance affinity, avidity,and specificity against complex target antigens (Ag) containing two ormore distinct epitopes.

FIG. 2 represents secondary stem-loop structures of DNA ligands oraptamers (SEQ ID NOs 3 and 4).

FIG. 3 shows how the aptamer beacons from FIG. 2 behaved as a functionof decreasing CTx peptide concentration.

FIG. 4A illustrates specificity of the 15-base CTx 2R-2h aptamer beaconfor the full-length 26-amino acid (AA) version of the CTx peptide.

FIG. 4B shows the same samples evaluated by a handheld fluorometer thatonly reports fluorescence peak height, but confirms the level ofspecificity.

FIG. 5 shows the relative linearity and sensitivity of the 15-base CTx2R-2h aptamer beacon assay.

FIG. 6A illustrates the ability to normalize urine concentrationreadings with simple aptamer beacon fluorescence readings.

FIG. 6B shows a quantitative estimation of creatinine and urea levels inurine or serum using the aptamer beacon denaturation approach.

FIG. 7A illustrates that the 2,942 dalton (26-amino acid) CTx bonepeptide can be extracted from urine to avoid the denaturing effects ofcreatinine and urea on the CTx 2R-2h aptamer beacon assay by use of adesalting size-exclusion polyacrylamide bead column.

FIG. 7B shows that CTx peptide extracted from human urine by means of adesalting column can still be detected to a level of at least 122 ng/mlby the CTx 2R-2h aptamer beacon.

FIG. 8 illustrates the secondary stem-loop structures of severalaptamers which dominated a sequenced pool of vitamin D3 aptamers(abbreviated VD3 and from the SEQ ID NOs 429-526).

FIG. 9 illustrates the FRET responses of loops A, B, and C for theaptamers shown in FIG. 8.

FIG. 10 reveal that the VD3 Loop C beacon appears to react equally wellwith (A) 1-hydroxy-vitamin D2, (B) 1-hydroxy-vitamin D3 and (C)25-hydroxy-vitamin D3.

FIG. 11 shows an assessment of the VD3 Loop C beacon.

FIG. 12 summarizes assessment of the specificity or cross-reactivity ofthe VD3 Loop C aptamer beacon versus a variety of potential analytes orinterfering species.

FIG. 13 shows fluorometric spectra from two separate trials of acompetitive displacement FRET assay.

FIG. 14 shows the same samples from FIG. 13 assessed for fluorescencepeak height.

FIG. 15 shows four examples of aptamers from the pool of aptamers thatbind recombinant human growth hormone.

FIG. 16 shows four more examples of aptamers from the pool of aptamersthat bind recombinant human growth hormone.

FIG. 17A shows an experimental matrix screening scheme for captureaptamer-conjugated magnetic microbeads.

FIG. 17B shows mean bar heights of three separate measurements.

FIG. 18 gives ECL line plots for assay combinations 18 and 40 from thematrix in FIG. 17A.

FIG. 19A shows an experimental matrix screening scheme for captureaptamer-conjugated magnetic microbeads.

FIG. 19B shows mean bar heights of three separate measurements.

FIG. 20A shows the linear ECL response for the sandwich assay of FIG.19.

FIG. 20B shows cross-reactivity of the combination number 4 BNP assayversus other peptide or protein analytes that might be found at the 100ng/ml level in human blood.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

There is no single preferred embodiment for use of the DNA aptamerligand sequences or linked aptamer constructs identified herein. Rather,the sequences are useful to varying extents in a variety of assayformats and sensors or diagnostic devices chosen from at least thefollowing list: lateral flow test strips, Surface Enhanced Raman (SERS),Surface Plasmon Resonance (SPR), Surface Acoustic or Transverse Wave(SAW or STW) detection, electrical, electrochemical, colorimetricabsorbance, agglutination, ELISA-like or enzyme-linked microplateassays, magnetic bead-based capture assays, ECL or otherchemiluminescence assays, radioisotopic assays and a variety offluorescence assays including, but not limited to, fluorescenceintensity, fluorescence lifetime, fluorescence polarization (FP) andFluorescence or Förster Resonance Energy Transfer (FRET) assays (bothbeacon and competitive FRET (Bruno et al., 2010, 2011) in round tubes,square or flat cuvettes, or immobilized on magnetic beads, other typesof microbeads, or flat surfaces such as nitrocellulose, nylon, or othermembranes or on glass or plastic DNA microarrays or “biochips.”

While there may appear to be considerable variability among sequencesthat bind the same clinical analyte targets, “epitopes” and theircognate aptamer binding sites are usually quite small (e.g., 5-10 bases)and a single target may contain numerous individual binding sites orepitopes for multiple aptamer binding. In addition, however, there isoften a common or consensus sequence (designated herein by slashesbetween clone numbers in Table 9, e.g. —aptamer clones CTx 2, 13, 19,20, 25, 32F or R series are identical and only listed once as SEQ ID NO3 and 4) or common segments of 5-10 or more nucleotides in a row withinotherwise different aptamer sequences that can bind a specific targetepitope that may dominate the other binding sites by being morephysically accessible or having stronger electrostatic, hydrogenbonding, or other attractive forces (summation of van der Waals or otherweak forces). Variations in nucleotide sequences around these consensussegments or common binding sequence segments may serve to modulate thebinding segment's affinity or specificity or may have no effect at all.These properties must be determined by empirical comparisons.

DNA Ligand (Aptamer) Selection and Generation

General methods for developing DNA ligands or aptamers to theimmobilized proteins, peptides, or small molecules (defined as less than1,000 daltons) are as follows. The protein, peptide or anamino-derivative of the small molecule (such as glucosamine in the caseof D-glucose or dextrose) is then added to 2×10⁹ tosyl-coated magneticbeads (MBs; e.g., Dynal brand from Invitrogen Corp. Carlsbad, Calif., 2.8 micron size) for 2 hours at 37° C. The tosyl group is a “leaving”group that allows the formation of a very stable covalent bond betweenprimary amine groups in the target protein, peptide or amino-derivatizedsmall molecule and therefore immobilizes the target on the surfaces ofthe MBs so that they can be used to probe the randomized DNA library forDNA ligands. Target molecule-conjugated MBs (or target-MBs) arecollected for 2 minutes in a magnetic collection device using anexternal magnet and the supernate is carefully withdrawn with a pipettetip. Target-MBs are then resuspended by vortexing briefly in 1× BindingBuffer (1×BB; 0.5M NaCl, 10 mM Tris-HCl, and 1 mM MgCl₂, pH 7.5-7.6,)and washed by agitation for 5 minutes. MBs are collected and washedthree times in this manner and then resuspended in 1 ml of 1×BB.

MB-based DNA ligand or aptamer development is then performed using atemplate library sequence such as:5′-ATCCGTCACACCTGCTCT-N₃₆-TGGTGTTGGCTCCCGTAT-3′, where N₃₆ representsthe randomized 36-base region of the DNA library (maximal sequencediversity=4³⁶ in theory). Primer sequences are: 5′-ATACGGGAGCCAACACCA-3′(designated forward) and 5′-ATCCGTCACACCTGCTCT-3′ (designated reverse)to prime the template and nascent strands for PCR, respectively. Therandom library is reconstituted in 500 μl of sterile nuclease-free waterand heated to 95° C. for 5 minutes to ensure that the DNA library iscompletely single-stranded and linear. The hot DNA library solution isadded to 100 μl of target-MBs (2×10⁸ beads) with 600 μl of sterile 2×Binding Buffer (2×BB). The DNA library and target-MB suspension (1.2 ml)is mixed at room temperature (RT, approximately 25° C.) for 1 hour.Target-MBs with any bound DNA (round 1 aptamers) are magneticallycollected. The DNA-target-MB complexes are washed three times in 400 μlof sterile 1×BB. Following the third wash, the DNA-target-MB pellet(about 75 μl) is used in a PCR reaction to amplify the bound DNA asfollows. The MB pellet is split into 15 μl aliquots and added to fivepre-made PCR tubes which contain most of the nonperishable ingredientsof a PCR reaction beneath a wax seal. A total of 3 μl of 1:10 primer mix(10% forward primer plus 10% reverse primer) in nuclease-free deionizedwater or ˜20 nanomoles of each primer per ml plus 1 μl (5 U) of Taq DNApolymerase and 5 μl of 2 mM MgCl₂ are added to each of the five tubes.PCR reactions are supplemented with 0.5 μl of E. coli single-strandbinding protein (SSBP, Stratagene Inc., La Jolla, Calif.) to inhibithigh molecular weight concatamer (end to end aggregates of the DNAligands) formation. PCR is carried out as follows: an initial 95° C.phase for 5 minutes, followed by 20 cycles of 1 minute at 95° C., 1minute at 53° C., and 1 minute at 72° C. followed by a 72° C. completionstage for 7 minute, and refrigeration at 4° C. This constitutes thefirst of multiple rounds of MB-aptamer development. Iterations of theMB-aptamer development process are repeated until the desired affinityor assay sensitivity and specificity are achieved. Typically, 5-10rounds of the MB-aptamer development process are required to achieve lowng/ml detection of target analytes. To begin the second round and allsubsequent rounds, 4 complete tubes of the original PCR tubes are heatedto 95° C. for 5 minutes to release bound DNA from the target-MBs. Thefifth tube is always retained and refrigerated as a back-up for thatround of the aptamer generation process. All available DNA (25 μl pertube) is siphoned out of the hot tubes without removing the target-MBsbefore the tubes cool significantly and the DNA is pooled. The 100 μl ofhot DNA is added to 100 μl of fresh target-MBs in 200 μl of 2×BB andallowed to mix for 1 hr at RT. Thereafter, the selection andamplification process are repeated for 3-8 more rounds with checking for72 bp aptamer PCR products by ethidium bromide-stained 2% agaroseelectrophoresis after each round. Following the last round of aptamerdevelopment, aptamers are cloned into chemically competent E. coli usinga cloning kit from Lucigen Corp. (Middleton, Wis.) and clones are sentto Sequetech, Inc. (Mountain View, Calif.) for DNA sequencing.

Screening of Aptamers for Highest Affinity, Lowest Cross-Reactivity andto Determine Lower Limit of Detection by Target Titration in ELISA-LikePlate Assay (“ELASA”)

To evaluate, screen, and rank aptamers based on affinity againstclinically relevant targets, an enzyme-linked plate assay is conductedby first immobilizing 100 μl of 1:10 diluted target (about 0.1 mg oftotal protein, peptide or small molecule) in 0.1M NaHCO₃ (pH 8.5)overnight at 4° C. in a covered polystyrene 96-well plate. The plate isdecanted and washed three times in 250 μl of 1×BB. Each of the different5′-biotinylated aptamers raised against the target is dissolved in 1×BBat 1.00 nmoles to 4.50 nmoles per 100 microliters and applied to theircorresponding plate wells for 1 hour at room temperature (RT; ˜25° C.)with gentle mixing on an orbital shaker. The plate is decanted andwashed three times in 250 μl of 1×BB for at least 5 minutes per washwith gentle mixing. One hundred μl of a 1:2,000 dilution ofstreptavidin-peroxidase from a 5 mg/ml stock solution in 1×BB is addedper well for 30 minutes at RT with gentle mixing. The plate is decantedand washed three times with 250 μl of 1×BB per well as before. Onehundred μl of ABTS (2,2′-azino-bis(3-ethylbenzthiazoline-6-sulphonicacid) substrate with stabilized hydrogen peroxide (Kirkegaard PerryLaboratories, Inc., Gaithersburg, Md.) is added per well for 10 minuteat RT. Finally absorbance is quantified using a microplate reader with405 nm optical filter.

As Tables 1-8 illustrate for several cardiovascular biomarker targets(Brain Natriuretic Peptide; BNP, D-Dimer; DD, Creatine Kinase-MB types Iand II; MBI and MB2, Interleukin-18; IL 18, and Troponin-T; Tpn all at(1 μg/ml) the initial ELASA screening is useful for ranking the relativeaffinity of aptamers for their respective targets by simple ranking ofabsorbance values at 405 nm from highest to lowest. Each of the Tables(1-8) illustrates general consistency between ELASA trials as well(i.e., the highest affinity aptamers consistently rank among the highestabsorbance values between ELASA trials or plates 1-4 maximally).

TABLE 1 DNA Ligand ELASA Rankings for Brain Natriuretic Peptide (BNP)Plate 1 Plate 2 Plate 3 Well Aptamer A 405 nm Well Aptamer A 405 nm WellAptamer A 405 nm A12 BNP - 6R 2.766 A12 BNP - 6R 2.171 A12 BNP - 6R2.285 C1 BNP - 14bF 2.283 A3 BNP - 2F 2.110 D5 BNP - 22F 2.272 A3 BNP -2F 2.276 C1 BNP - 14bF 2.089 E3 BNP - 25cF 2.240 B1 BNP - 7F 2.227 A8BNP - 4/9R 1.989 D4 BNP - 21bR 2.212 E3 BNP - 25cF 2.215 A1 BNP - 1F1.987 C1 BNP - 14bF 2.206 A1 BNP - 1F 2.184 B9 BNP - 13F 1.986 B4 BNP -8R 2.197 B4 BNP - 8R 2.176 A9 BNP - 5/11/15b/19/25bF 1.977 A9

 P - 5/11/15b/19/25 2.196 A8 BNP - 4/9R 2.163 C2 BNP - 14bR 1.971 A3BNP - 2F 2.176 C3 BNP - 15aF 2.162 D9 BNP - 23bF 1.961 C3 BNP - 15aF2.165 D4 BNP - 21bR 2.149 B4 BNP - 8R 1.953 B5 BNP - 10F (70) 2.157

indicates data missing or illegible when filed

TABLE 2 DNA Ligand ELASA Rankings for D-Dimer (DD) Plate 1 Plate 2 Plate3 Plate 4 Well Aptamer A 405 nm Well Aptamer A 405 nm Well Aptamer A 405nm Well Aptamer A 405 nm A10 DD - 5R 1.888 A10 DD - 5R 1.809 B1 DD - 7F(71) 0.803 C1 DD - 14F (71) 0.816 B10 DD - 12R 1.427 A4 DD - 2R (71)1.620 C1 DD - 14F (71) 0.652 B1 DD - 7F (71) 0.806 C7 DD - 17F (71)1.261 C7 DD - 17F (71) 1.237 A10 DD - 5R 0.576 A10 DD - 5R 0.749 B8 DD -11R (71) 1.122 B10 DD - 12R 1.213 B4 DD - 9R (71) 0.545 B10 DD - 12R0.732 B12 DD - 13R (71) 1.088 A12 DD - 6R (71) 1.005 B2 DD - 7R (71)0.510 B4 DD - 9R (71) 0.645 B1 DD - 7F (71) 1.027 B7 DD - 11F (71) 1.003C4 DD - 15R 0.508 C3 DD - 15F 0.635 B7 DD - 11F (71) 1.021 B8 DD - 11R(71) 0.986 B5 DD - 10F (71) 0.418 B5 DD - 10F (71) 0.563 B2 DD - 7R (71)1.017 B1 DD - 7F (71) 0.964 C12 DD - 20R (71) 0.404 B2 DD - 7R (71)0.535 A12 DD - 6R (71) 0.989 C11 DD - 20F (71) 0.932 B10 DD - 12R 0.386A5 DD - 3F (71) 0.526 C12 DD - 20R (71) 0.952 B6 DD - 10R (71) 0.930 A5DD - 3F (71) 0.370 C4 DD - 15R 0.512

TABLE 3 DNA Ligand ELASA Rankings for Creatine Kinase-MB Type I (MBI)Plate 1 Plate 2 Plate 3 Plate 4 Well Aptamer A 405 nm Well Aptamer A 405nm Well Aptamer A 405 nm Well Aptamer A 405 nm F1 MBI - 20F 2.917 F1MBI - 20F 2.692 F1 MBI - 20F 1.863 F1 MBI - 20F 1.948 D2 MBI -1/4/5/8/9/17R 2.725 D2 MBI - 1/4/5/8/ 2.680 D2 MBI - 1/4/5/8/ 1.858 D3MB

- 2

1.823 (71) 9/17R (71) 9/17R (71) D6 MBI - 3R (70) 2.668 D6 MBI - 3R (70)2.647 D3 MBI - 2F (71) 1.808 D6 MBI - 3R (70) 1.746 E10 MBI - 16R 2.665E1 MBI - 11F 2.612 E3 MBI - 12F (70) 1.753 D2 MBI - 1/4/5/8/ 1.744 9/17R(71) E1 MBI - 11F 2.658 E10 MBI - 16R 2.612 E2 MBI - 11R 1.716 F2 MBI -20R 1.742 E2 MBI - 11R 2.651 D3 MBI - 2F (71) 2.511 E5 MBI - 14/18F1.692 D1 MBI - 1/4/5/8/ 1.733 9/17F (71) E11 MBI - 19F (69) 2.589 E2MBI - 11R 2.499 D4 MBI - 2R (71) 1.663 E2 MBI - 11R 1.659 E7 MBI - 15F2.578 D1 MBI - 1/4/5/8/ 2.497 E4 MBI - 12R (70) 1.642 E3 MBI - 12F (70)1.647 9/17F (71) D1 MBI - 1/4/5/8/9/17F 2.556 F2 MBI - 20R 2.424 E1MBI - 11F 1.640 D5 MBI - 3F (70) 1.629 (71) D4 MBI - 2R (71) 2.522 D4MBI - 2R (71) 2.419 F2 MBI - 20R 1.619 D4 MBI - 2R (71) 1.607

indicates data missing or illegible when filed

TABLE 4 DNA Ligand ELASA Rankings for Creatine Kinase-MB Type II (MBII)Plate 1 Plate 2 Well Aptamer A 405 nm Well Aptamer A 405 nm G1 MBII 6/8F2.206 G1 MBII 6/8F 2.120 G12 MBII - 12R 2.191 G4 MBII - 7R 1.931 (71)F12 MBII - 5R 2.173 G12 MBII - 12R (71) 1.850 H6 MBII - 14R 1.989 H5MBII - 14F 1.688 G4 MBII - 7R 1.910 F7 MBII - 3F (71) 1.682 H7 MBII -15F 1.838 G5 MBII - 9F 1.675 (71) G11 MBII - 12F 1.827 G11 MBII - 12F(71) 1.640 (71) H5 MBII - 14F 1.794 H7 MBII - 15F (71) 1.611 F10 MBII -4R (71) 1.751 F12 MBII - 5R 1.588 G9 MBII - 11F 1.732 F9 MBII - 4F (71)1.586

TABLE 5 DNA Ligand ELASA Rankings for Interleukin-18 (IL18) Plate 1Plate 2 Plate 3 Plate 4 Aptamer Well A 405 nm Aptamer Well A 405 nmAptamer Well A 405 nm Aptamer Well A 405 nm IL18 - 29F D1 1.433 IL18 -22R C4 1.738 IL18 - 29F D1 1.288 IL18 - 21R C2 1.060 IL18 - 10F B1 1.428IL18 - 21R C2 1.697 IL18 - 21R C2 1.202 IL18 - 26F (71) C7 0.841 IL18 -5F A7 1.393 IL18 - 10F B1 1.673 IL18 - 22R C4 0.993 IL18 - 4R A6 0.835IL18 - 22R C4 1.373 IL18 - 29F D1 1.655 IL18 - 10F B1 0.917 IL18 - 22FC3 0.677 IL18 - 21R C2 1.367 IL18 - 5F A7 1.596 IL18 - 26F (71) C7 0.886IL18 - 22R C4 0.662 IL18 - 21F C1 1.270 IL18 - 22F C3 1.594 IL18 - 22FC3 0.855 IL18 - 27/31F (70) C9 0.613 IL18 - 29R D2 1.219 IL18 - 26F (71)C7 1.553 IL18 - 2F A1 0.844 IL18 - 33R D8 0.608 IL18 - 3F A3 1.217IL18 - 21F C1 1.534 IL18 - 29R D2 0.795 IL18 - 27/31R (70) C10 0.601IL18 - 15R B6 1.209 IL18 - 29R D2 1.528 IL18 - 5F A7 0.791 IL18 - 5F A70.589 IL18 - 22F C3 1.204 IL18 - 30F (71) D3 1.525 IL18 - 4R A6 0.785IL18 - 29F D1 0.550

TABLE 6 DNA Ligand ELASA Rankings for Troponin-T (Tpn) Plate 1 Plate 2Plate 3 Plate 4 Aptamer Well A 405 nm Aptamer Well A 405 nm Aptamer WellA 405 nm Aptamer Well A 405 nm Tpn - 20F (71) H3 2.325 Tpn - 20F (71) H32.642 Tpn - 20F (71) H3 2.482 Tpn - 20F (71) H3 2.507 Tpn - 12R (71) G22.070 Tpn - 20R (71) H4 2.479 Tpn - 20R (71) H4 2.249 Tpn - 20R (71) H42.259 Tpn - 20R (71) H4 2.053 Tpn - 1F (71) E1 2.374 Tpn - 16R (71) G101.854 Tpn - 16F (71) G9 1.525 Tpn - 7F (71) F3 2.030 Tpn - 12R (71) G22.357 Tpn - 16F (71) G9 1.811 Tpn - 6R (71) F2 1.514 Tpn - 18F H1 1.986Tpn - 6R (71) F2 2.342 Tpn - 6R (71) F2 1.656 Tpn - 16R (71) G10 1.507Tpn - 18R H2 1.971 Tpn - 18R H2 2.304 Tpn - 7F (71) F3 1.599 Tpn - 18FH1 1.396 Tpn - 6R (71) F2 1.962 Tpn - 7F (71) F3 2.298 Tpn - 15R (71) G81.535 Tpn - 11F (71) F11 1.386 Tpn - 1R (71) E2 1.949 Tpn - 12F (71) G12.252 Tpn - 9R F8 1.517 Tpn - 4bR (71) E10 1.350 Tpn - 15F (71) G7 1.898Tpn - 1R (71) E2 2.249 TPn - 1F (71) E1 1.487 Tpn - 1F (71) E1 1.318Tpn - 1F (71) E1 1.871 Tpn - 6F (71) F1 2.195 Tpn - 4bR (71) E10 1.477Tpn - 7F (71) F3 1.264

TABLE 7 DNA Ligand ELASA Rankings for C-Reactive Protein (CRP) RankAptamer Abs 405 nm 1 CRP-5R 2.332 2 CRP-10R 2.27 3 CRP-2R 2.210 4CRP-11R 2.173 5 CRP-17R 2.165 6 CRP-23F 2.139 7 CRP-10F 2.100 8 CRP-2F2.072 9 CRP-9R 2.066 10 CRP-9F 2.055

TABLE 8 DNA Ligand ELASA Rankings for Myoglobin (Myo) Rank Aptamer Abs405 nm 1 Myo-3R/4R 2.395 2 Myo-22F 2.367 3 Myo-15F 2.344 4 Myo-3F/6F2.337 5 Myo-5R 2.327 6 Myo-24F 2.294 7 Myo- 2.272 18R/27F 8 Myo-15R2.269 9 Myo-28F 2.264 10 Myo-8F 2.250

Aptamer Beacons and Competitive FRET-Aptamer Assays

Once key aptamers have been identified by the commonality of theirsequences or their secondary stem-loop structures, the assay developerdecides upon secondary structure loops (potential binding pockets) tolabel with a fluorophore (F) or quencher (Q) as illustrated by dottedlines that define the borders or limits of potential binding loops inFIGS. 2 and 8. Secondary stem-loop structures are easily generated byGibbs free energy minimization with common software such as M-fold andVienna RNA (using DNA parameters) that is freely available for publicuse. The researcher or inventor simply enters the DNA sequence andselects a temperature and secondary stem-loop structures like thoseshown in FIG. 2 are generated. At this point, one can empirically assesscandidate aptamer “beacon” potential in FRET analyte titrationexperiments such as those shown in FIG. 3. The suspected short aptamerbeacon loop is re-synthesized independent of the original larger parentaptamer sequence with a fluorophore (F) such as TYE 665 attached to the5′ end and a matched quencher (Q) such as Iowa Black attached to the 3′end (or vice versa), purified by HPLC or other form of chromatographyand assessed for fluorescence output or intensity as a function ofdifferent levels of the target analyte (e.g., FIGS. 3 and 9). Thegreatest separation of fluorescence peak values or spectral emissions(e.g., FIGS. 3 and 9) is used to define the optimal beacon sinceseparation of fluorescence values as a function of analyte concentrationis essentially the definition of a good quality fluorescence assay.

Alternatively, one may label the suspected binding loops internally andplace an F or a Q somewhere in the mid-section of the suspected loopother than the 3′ or 5′ end (i.e., intrachain FRET). Attachment of F orQ is usually accomplished via succinimide linkage of F- orQ-succinimides added to amino-modified aptamers at specifically chosenlocations in the binding pockets. Primary amine linker moieties such asthe “UniLink™” can be added internally at the time of chemical synthesisof aptamers. Typically 1 mg or more of an aptamer sequence issynthesized with a primary amine linker moiety (UniLink™) located at theapproximate center of each loop structure (suspected binding pockets).Each of these internally amine-labeled aptamers is then labeled with 100μl (0.1 mg) of F-succinimide (or alternatively Q-succinimide) for 2hours in a 37° C. incubator, followed by purification through a1×BB-equilibrated PD-10 (Sephadex G-25; GE Healthcare) column. In themeantime, an equal molar amount of primary amine-modified targetmolecule is labeled with 0.1 mg of spectrally matched Q-succinimide (toaccept photons from F) at 37° C. for 2 hours and then washed three timesby centrifugation at 14,000 rpm for 10 minutes per wash and resuspensionin 1 ml of 1×BB. “Spectrally matched” means that most of the wavelengthsof light emitted by F can be effectively absorbed by Q because itsabsorbance spectrum largely overlaps the emission spectrum of F.Naturally, if the aptamer is labeled with a Q-succinimide in thealternate form of the assay, the amine-modified target must be labeledwith an appropriately matched F-succinimide to be quenched when bound tothe Q-labeled aptamer. Pooled one ml fractions of purified F-labeled DNAaptamers are mixed with an equimolar amount of Q-labeled-amino-targetanalyte (or vice versa in the alternate embodiment) for 30 minutes at RTwith mixing in 1×BB or phosphate buffered saline (PBS, 0.1M phosphatesin 8.5 g/L sodium chloride at pH 7.2 to 7.4) and then purified throughan appropriate size-exclusion chromatography column (according tomolecular weight of the combined F-aptamer plus Q-target complex) toproduce a purified “competitive FRET complex” consisting of F-aptamerconjugate bound to Q-labeled target. This competitive FRET complex canlater be competed against unlabeled cognate analyte concentrations toincrease the fluorescent light output of the liquid assay system andquantify the unlabeled analyte concentration.

Generally, the aptamer beacons or competitive FRET-aptamer complexes arethen diluted to a final concentration of 1-5 μg/ml in 1×BB and equallydispensed to polystyrene or methacrylate cuvettes in which 1 ml ofunlabeled target at various concentrations in 1×BB, PBS or dilutedblood, plasma, serum, saliva, aspirate or urine has been added already.Cuvettes are gently mixed for 15 to 20 minutes at RT prior to readingtheir fluorescence in the homogeneous beacon or competitive-displacementFRET assay formats using a spectrofluorometer having gratings to varythe excitation wavelength and emission scanning ability or a stationary,handheld or otherwise portable fluorometer having a more restricted orfixed excitation and emission optical filter set with a range ofwavelengths for excitation and emission.

Aptamer or Aptamer Binding Site Linkage in One or More Dimensions

The linkage of binding sites is beneficial in terms of enhancingreceptor affinity, avidity (tensile binding strength), and selectivityversus complex targets with two or more distinct epitopes. This linkagecan be sequential and linear (one-dimensional as in antibody heavy andlight chain linkage of HV regions, FIG. 1A) or could be expanded intotwo or three dimensions much like DNA dendrimers or other more complexstructures known to those skilled in the art. Linear linkage by chemicalsynthesis is quite facile, if one knows that aptamer DNA sequences orshorter (approximately 5-10 base) binding site sequences to be linked.One can simply design one long sequence to incorporate the desiredaptamers or binding sites with repetitive poly-adenine (A),poly-cytosine (C), poly-guanine (G), poly-thymine (T), poly-uridine (U),or other intervening sequences that are unlikely to bind the targetepitopes. The length of the composite aptamer construct will be limitedby current chemical synthesis technology to about 200 bases. However,cellular biosynthesis or enzymatic synthesis by polymerase chainreaction (PCR) or asymmetric PCR (producing predominatelysingle-stranded ss-DNA from a template) would not be so limited andshould produce aptamer constructs up to 2,000 bases before the Taqpolymerase falls off the template. The 2 kilobase Taq polymerase limitis the basis for the well-known RAPD (Random Amplification ofPolymorphic DNA) method of DNA or genetic “fingerprint” analyses inwhich primers greater than 2 kilobases apart fail to produce a PCRproduct or amplicon, because Taq becomes disengaged from the templateDNA before traveling 2,000 bases. In this way, lengthy aptamerconstructs of less than 2 kilobases could be made from complementary DNAtemplates that would enable binding of different epitopes that aredistal on the surface of relatively large objects such as viruses andwhole bacterial or eukaryotic cells. Again, poly-A, C, G, T, or U orother linker nucleotide segments could be designed into the cDNAtemplate to produce the resultant nascent strand to ligate aptamers oraptamer binding sites together into one contiguous linear chain withintervening linkers.

For 2-D or 3-D linked aptamer structures a variety of linker chemistriesare available, but the preferred embodiment is probably addition of aUniLink™ primary amine group somewhere in the mid-section of a largermulti-aptamer construct followed by covalent linkage of two or more suchmulti-aptamer constructs by means of bifunctional linkers such as lowlevels (<1%) of glutaraldehyde, carbodiimides, sulfo-EGS, sulfo-SMCC orother such bifunctional linkers familiar to those skilled in conjugatechemistry. This strategy would result in a larger flower-like 2-D or 3-Dstructure consisting of two or more lengthy multi-aptamer structures.

Referring to the figures, FIG. 1A is illustrates the general structureof an IgG antibody showing the linkage of hypervariable (HV) amino acidregions used for actual binding to target epitopes on complex antigens.Linear linkage of HV binding sites adds affinity, avidity andspecificity the antibody binding to complex targets. Likewise in FIG.1B, aptamers or their shorter (5-10 base) binding sites can be linkedduring chemical or biochemical (enzymatic) synthesis to enhance aptamerbinding affinity, avidity or specificity for improved assay sensitivityand selectivity.

FIG. 2 is a diagram of secondary structures for two “finalists” (SEQ IDNOs 3 and 4) from the pool of 24 unique candidate aptamers (SEQ ID NOs.1-24) that bind human Type I bone collagen C-telopeptide (CTx)indicative of bone loss when found in the urine. These 2 aptamersequences (forward and reverse or F and R-primed) dominated the aptamerpool (12 of 38 total clones=31.6%) and were therefore considered primecandidates to investigate for possible binding pockets (secondary loopstructures). These potential binding pockets are shown as loops cut offfrom the rest of the aptamer by dotted lines and designated according tothe 12 hour clock as 2 O'clock (or second hour or 2 h), 6 O'clock (6 h)and 10 O'clock (10 h). The overall 5′ and 3′ ends as well as a numberingsystem from bases 1 (at the 5′ end) to base 72 (at the 3′ end) are alsoindicated. A variation on the CTx 2R-2h loop or beacon consisting of 13and 15 bases (13b or 15b) is also indicated. The 2 O'clock or secondhour (2 h) aptamer was subsequently synthesized to produce an aptamerbeacon (3′ end labeled with a quencher molecule and the 5′ end labeledwith a fluorophore) as demarcated by the dotted lines which is capableof detecting CTx peptide to low nanogram per ml levels.

FIG. 3 shows how each of the aptamer beacons derived and defined fromFIG. 2 behaved as a function of decreasing CTx peptide concentration(serial two-fold dilutions beginning with 100 micrograms per ml andending with zero CTx peptide) in 1× binding buffer (1×BB; 0.5 M NaCl, 10mM Tris-HCl, pH 7.5-7.6, 1 mM MgCl₂). In the figure “h” means hour orO'clock so that 2 h refers to the 2 O'clock loop from FIG. 2, while Fmeans forward-primed and R means reverse-primed by reference to FIG. 2as well. FIG. 3 demonstrates that there is in fact a significantdifference in the ability of each candidate loop or candidate beaconfrom FIG. 2 to bind and detect a 26-amino acid (AA; full-length) CTxpeptide in 1×BB. The figure shows that the 15-base CTx 2R-2h loop(5′-GGTGGTGTTGGCTCC-3′) acts as a superior aptamer beacon for detectionof CTx peptide, because it gives the greatest fluorescence spread as afunction of CTx peptide concentration. The CTx 2R-2h loop was optimalfor FRET-based detection because it gives the greatest spread orseparation for various two-fold serial dilutions of the 26-AA CTxpeptide beginning at 100 μg/ml. The CTx 2F-10h loop was also noteworthy,but could not discriminate many of the different CTx concentrations. Thecandidate loops or beacons from this experiment were 5′ labeled withTYE665 fluorophore and 3′ labeled with Iowa Black RQ quencher andHPLC-purified prior to use at Integrated DNA Technologies, Inc.(Coralville, Iowa). Excitation on a spectrofluorometer was at 645 nmwith 5 nm slits and a PMT (photomultiplier tube) setting of 900 V. Aslightly shorter 13-base version of the CTx-2R-2h beacon((5′-GTGGTGTTGGCTC-3′) has also been shown to work almost as well as the15-base version, but has slightly higher background fluorescence.Excitation in all cases was at 645±5 nm to maximally excite TYE 665 dye(fluorophore) on the 5′ end of each potential aptamer beacon with aphotomultiplier tube (PMT) detector setting of 1,000 Volts.

FIGS. 4A and B demonstrate relative specificity of the CTx 2R-2h aptamerbeacon. FIG. 4A illustrates specificity or preference of the beacon forbinding to the full-length 26-AA version of the CTx peptide based on itsmore intense fluorescence with the full-length CTx peptide, but not witha shorter 8-amino acid segment of the same peptide using aspectrofluorometer. Since the 8-AA version of the CTx peptide (oneletter amino acid sequence: EKAHDGGR) represents a subset of the larger26-AA peptide (amino acid sequence: SAGFDFSFLPQPPQEKAHDGGRYYRA), thisobservation indicates where the aptamer does not bind on the larger CTxpeptide and narrows down the possible binding sites to SAGFDFSFLPQPPQ orYYRA). The aptamer beacon does unexpectedly cross-react with and bind anepitope on bovine serum albumin (BSA) and since the 607 amino acid BSAprotein shares its longest region of commonality with the CTx peptide atthe amino acid sequence SFL or serine-phenylalanine-leucine, this may bethe actual binding site of the CTx 2R-2h aptamer beacon to CTx bonepeptide, although other sites cannot be ruled out completely. Again,intact bovine proteins and epitopes are not expected in human clinicalsamples, making the CTx 2R-2h aptamer beacon specific for its targetbone peptide.

FIG. 4B shows the same samples FIG. 4A evaluated by a handheldfluorometer that only reports fluorescence peak height, but confirms thelevel of specificity seen in the spectra above. The beacon was again 5′labeled with TYE665 fluorophore and 3′ labeled with Iowa Black quencherand HPLC-purified prior to use in assays. Excitation on thespectrofluorometer was at 645 nm with 5 nm slits and a PMT(photomultiplier tube) setting of 900 V. Handheld fluorometer valueswere obtained with an optically modified (red light emitting diode withpeak excitation at 650 nm with a 660-720 nm emission filter)Quantifluor™ device from Promega Corp. Other abbreviations used in FIG.3 are: NTx; N-terminal telopeptide of human Type I bone collagen, HP;helical peptide of human bone, BSA; bovine serum albumin, DPD;deoxypyridinoline, and Pyd; pyridinoline.

FIG. 5 compares the 15-base CTx 2R-2h aptamer beacon assay's titrationversus different levels of the full-length CTx peptide (26 amino acids)in 1× binding buffer for 30 minutes at room temperature as assessed bythe handheld Quantifluor™ from 0 to 32 ng/ml of CTx peptide with a limitof detection (LOD) of 1 ng/ml with a photodiode standard value settingof 999.0. It shows the relative linearity and sensitivity of the 15-baseCTx 2R-2h aptamer beacon assay.

FIG. 6 illustrates the linear normalization response of three differentaptamer beacons raised against creatinine from the SEQ ID NOs 239-294family to the denaturing effects of creatinine across the physiologicrange found in human urine. The non-specific linear response of aptamerbeacons in general to the denaturing (linearizing) effects of creatinineand urea across the physiologic range of these substances found in humanurine suggest that addition of almost any aptamer beacon to urine couldbe used to estimate creatinine and urea levels in urine and normalizethe values for other analytes in urine. It is a common practice inclinical diagnostics in which the creatinine or urea level of urine isused as a divisor for the amount of other analytes detected in urine tonormalize readings between different patients. In essence, thecreatinine or urea levels indicate how concentrated the urine is andthat information can be used to adjust or normalize (divide by) thecreatinine level to place the levels of other analytes in properperspective (i.e., high analyte levels in a dehydrated individual may bemisleading). Quantitative estimation of creatinine and urea levels inurine or serum using the aptamer beacon denaturation approach is simple(one step bind and detect), rapid (within 10-15 minutes) and facile ascompared to the more complicated multi-component alkaline picratecolorimetric and time-consuming Jaffe method (i.e., results obtainedgreater than 35 minutes after reagent and sample preparation).

FIG. 7 illustrates that the 2,942 dalton (26 amino acid) CTx peptide canbe extracted from urine to avoid the denaturing effects of creatinineand urea on the CTx 2R-2h aptamer beacon assay (demonstrated in FIG. 5)by use of a desalting size-exclusion polyacrylamide column. FIG. 7Ashows fractions collected from a desalting column (with a 1,800 daltonmolecular weight cut off) and run in an 8% polyacrylamide-sodium dodecylsulfate (SDS) electrophoresis gel which was run against molecular weightprotein standards (last lane) and Coomassie blue stained to reveal thelocation of the 2.9 kilodalton CTx peptide which emerged in the voidvolume fractions 4 and 5 (boxed). The far right lane of this gel showsmolecular weight protein standards beginning at 5 kD. FIG. 7B shows thatCTx peptide extracted from human urine by means of a desalting columncan still be sensitively detected to a level of at least 122 ng/ml bythe CTx 2R-2h aptamer beacon.

FIG. 8 illustrates the secondary stem-loop structures of severalcandidate aptamers (SEQ ID NOs 433 and 434) which dominated: thesequenced pool of vitamin D3 aptamers (abbreviated VD3 and from the SEQID NOs 429-526). Again, the lines and capital letters demarcate theloops which were considered further as binding pockets or for aptamerbeacons to detect vitamin D and its isoforms or congeners.

FIG. 9 illustrates the FRET responses of loops A, B, and C for the VD3aptamers shown in FIG. 8 as well as handheld (Quantifluor™-P)fluorometer peak fluorescence values as a function of 25-hydroxy-vitaminD3 (calcidiol) level in 1×BB. Loop C (5′-ACTATGGT-3′) proved to be theoptimal aptamer beacon based on its maximal spread or separation offluorescence spectra as a function of vitamin D concentration as shownin the upper right quadrant after Loop C was separately synthesized with5′-TYE 665 dye and 3′-Iowa Black quencher to convert it into a beaconfor the titration experiment. The spectra were obtained by serialtwo-fold dilutions of calcidiol beginning at 100 μg/ml in 1×BB. Thecandidate VD3 loop beacons were 5′ labeled with TYE665 fluorophore and3′ labeled with Iowa Black quencher and HPLC-purified prior to use inassays. Excitation on a spectrofluorometer was at 645 nm with 5 nm slitsand a PMT setting of 900 V. Handheld fluorometer values (lower rightquadrant) were obtained with an optically modified (red light emittingdiode with peak excitation at 650 nm with a 660-720 nm emission filter)Quantifluor™-P device from Promega Corp. and show a lower limit ofdetection of about 195 ng/ml in 1×BB.

FIG. 10 shows that the VD3 Loop C beacon appears to react equally wellwith 1-hydroxy vitamin D2, 1-hydroxy-vitamin D3 and 25-hydroxy-vitaminD3 as assessed by spectrofluorometry in 1×BB (binding buffer). Hence theLoop C beacon is only specific for the vitamin D family and cannotdiscriminate individual congeners. Cross-reactivity is not problematicsince a number of immunoassays for vitamin D detect the total of themajor forms of vitamin D2 and D3 together. Hence, the inability of theLoop C VD3 aptamer to discriminate the minor variants of vitamin D isnot viewed as a limiting factor. The figure again shows serial two-folddilutions for each of the types of vitamin D beginning at 100 μg/ml in1×BB with 1-hydroxy-vitamin D2 spectra in the top panel,1-hydroxy-vitamin D3 spectra in the middle panel, and 25-hydroxy-vitaminD3 spectra in the bottom panel.

FIG. 11 shows a graphical assessment of the VD3 Loop C beacons by thehandheld fluorometer (Quantifluor™-P) in 1×BB across a range of variousvitamin D concentrations and for various forms of vitamin D. Thehandheld reader was modified with a red-emitting (650 nm) LED lightsource and 660-720 nm emission filter to better work in serum where thered region optics (>600 nm) can avoid much of the blue-green (<600 nm)autofluorescence background of blood, serum or urine. The range shown onthe x-axis spans much higher levels than previously shown. Some of thehigher levels are not physiological, but might be relevant to detectionof vitamin D is some vitamin-rich foods or dairy products. Lines of bestfit, whether linear or exponential, are shown for the three differenttypes of vitamin D congeners as well. The highest standard valuephotodetector setting of 999.0 was used in all cases.

FIG. 12 further assesses the specificity or cross-reactivity of the VD3Loop C aptamer beacon versus a variety of potential analytes orinterfering species commonly found in blood and urine by the customizedhandheld fluorometer (FIG. 12A) and by spectrofluorometry (FIG. 12B)H-DPD; hydroxy-deoxypyridinoline and H-Pyd; hydroxyl-pyridinoline crosslinkers from bone.

FIG. 13 shows fluorometric spectra from two separate trials of acompetitive displacement FRET assay using the VD3 Loop C beacon versusvarious levels of 25-hydroxy-vitamin D3 (two-fold serial dilutionsstarting at 100 μg/ml) in 1×BB. In this case, 25-hydroxy-vitamin D3 waslabeled with carboxyfluorescein by Fisher esterification (reaction of ahydroxyl group on the vitamin with a carboxyl group on the fluoresceinto form a covalent ester bond at acidic pH of approximately 5) followedby binding to appropriately quencher-labeled VD3 aptamer Loop C andcompetition against levels of calcidiol ≦100 micrograms per ml).

FIG. 14 shows the same samples from FIG. 13 assessed for fluorescencepeak height by the customized red-emitting handheld fluorometer assessedwith the highest standard value photodetector setting of 999.0. Thecompetitive FRET-aptamer assay appears to have a detection limit between156 to 312 ng/ml in these experiments.

FIG. 15 shows four examples of aptamers from the SEQ ID NOs 325-526 thatbind recombinant human growth hormone (r-hGH; >95% pure research grade)better than the natural form of hGH or somatotropin in ELISA-like assaysto help discriminate the artificial form of hGH in potential drug ordoping tests for athletes, or to monitor serum levels of exogenous dosesof r-hGH administered to children with growth deficits. The ELISA-likeassays were conducted with the named aptamers (SEQ ID NOs 336, 338, 343and 345) instead of antibodies in each case and absorbances were red at405 nm with an automated microplate reader after a 15 minute developmenttime in the presence of ABTS substrate as is standard in the diagnosticsindustry.

FIG. 16 shows four more examples of aptamers (from the SEQ ID NOs325-526) that bind recombinant human growth hormone (“r-hGH”) betterthan the natural form of hGH or somatotropin to help discriminate theartificial form in potential drug or doping tests for athletes andgrowth-challenged children. The ELISA-like assays were conducted withthe named aptamers (SEQ ID NOs 348, 377, 379 and 388) instead ofantibodies in each case and absorbances were red at 405 nm with anautomated microplate reader after a 15 minute development time in thepresence of ABTS substrate as is standard in the diagnostics industry.

FIG. 17A shows an experimental matrix screening scheme for captureaptamer-conjugated magnetic microbeads to be mixed with rutheniumtrisbipyridine (Ru(bpy)₃ ²⁺)-labeled reporter aptamers in a sandwichassay scheme to determine which of the 7×7 top hGH and r-hGH aptamercombinations (numbered 1-49 in the scheme table) gave the strongestelectrochemiluminescence (“ECL”) signal versus 10 pg/ml of r-hGH usingan IGEN International Origen® ECL analyzer in phosphate buffered salinecontaining 0.2 M tripropylamine (“TPA”). ECL was induced by ramping theelectrode voltage to 1.25 V.

FIG. 17B shows the results of this ECL matrix screening process. Meanbar heights of three separate measurements are plotted with standarddeviation error bars and the best (most intense ECL) combinations aremarked with asterisks.

FIG. 18 gives ECL line plots for assay combinations 18 and 40 from thematrix in FIG. 17A as a function of natural hGH concentrations showingsub-picogram and sub-nanogram per ml detection limits and relativelinearity over the hGH ranges indicated in 50% human serum (serumdiluted 1:1 in 1×BB buffer). The difference in assay regression lineslope is due to doubling of the amount of aptamer-coated magnetic beadsand reporter aptamer per tube in two different assay trials.

FIG. 19A shows an experimental matrix screening scheme for captureaptamer-conjugated magnetic microbeads to be mixed with rutheniumtrisbipyridine (Ru(bpy)₃ ²⁺)-labeled reporter aptamers in a sandwichassay scheme to determine which of the 4×4 top Brain or B-typeNatriuretic Peptide (“BNP”) aptamer combinations numbered 1-16 (andselected from the SEQ ID Nos. 527-562) gave the strongest ECL signalversus 100 ng of BNP using an IGEN International Origen® ECL analyzer inphosphate buffered saline containing 0.2 M TPA.

FIG. 19B shows the results of this ECL matrix screening process. Barheights represent the means of three separate measurements plotted withstandard deviation error bars and the best (most intense ECL)combinations are marked with asterisks.

FIG. 20A shows the linear ECL response for combination 4 (see FIG. 19A)sandwich assay versus picogram per ml levels of BNP in a 50% human serumand 1×BB diluent environment.

FIG. 20B shows cross-reactivity of the combination number 4 BNP assayversus other peptide or protein analytes that might be found at the 100ng/ml level in human blood.

Although the invention and DNA ligand (aptamer) sequences have beendescribed with reference to specific embodiments, these descriptions arenot meant to be construed in a limited sense. Various modifications ofthe disclosed embodiments, as well as alternative embodiments of theinventions will become apparent to persons skilled in the art uponreference to the description of the invention. It is, therefore,contemplated that the appended claims will cover such modifications thatfall within the scope of the invention.

TABLE 9 Final Clinical Analyte Aptamer List 2011 <SEQ ID NO 1 CTx 1F;DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACTAACTTGTTGCTGATCTTATCCAGAGCAGGTGTGACGGAT <SEQ ID NO 2CTx 1R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGGATAAGATCAGCAACAAGTTAGTGGTGTTGGCTCCCGTAT <SEQ ID NO 3CTx 2/13/19/20/25/32F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACCCGTTTTTGATCTAATGAGGATACAATATTCGTCTAGAGCAGGTGTGACGGAT<SEQ ID NO 4 CTx 2/13/19/20/25/32R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTAGACGAATATTGTATCCTCATTAGATCAAAAACGGGTGGTGTTGGCTCCCGTAT<SEQ ID NO 5 CTx 3F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAATCGATGGTTAGACTATTACACTAGATGGAATTCATAGAGCAGGTGTGACGGAT<SEQ ID NO 6 CTx 3R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTATGAATTCCATCTAGTGTAATAGTCTAACCATCGATTGGTGTTGGCTCCCGTAT<SEQ ID NO 7 CTx 6F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAATCTGCCGACTAGGCCAAGTAATTATATTCAGCTGGAGAGCAGGTGTGACGGAT<SEQ ID NO 8 CTx 6R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCCAGCTGAATATAATTACTTGGCCTAGTCGGCAGATTGGTGTTGGCTCCCGTAT <SEQ ID NO 9 CTx 7/8F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACAGCTGATATTGGATGGTCCGGCAGAGCAGGTGTGACGGAT <SEQ ID NO10 CTx 7/8R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGCCGGACCATCCAATATCAGCTGTGGTGTTGGCTCCCGTAT <SEQ ID NO11 CTx 11F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACATTACAATAGATGTATTGACATATCCGGACAGTCGAGAGCAGGTGTGACGGAT<SEQ ID NO 12 CTx 11R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCGACTGTCCGGATATGTCAATACATCTATTGTAATGTGGTGTTGGCTCCCGTAT<SEQ ID NO 13 CTx 14F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACTCGTGTAGTGCTGTCTTTGTGGAATCCTTGCATCGAGAGCAGGTGTGACGGAT<SEQ ID NO 14 CTx 14R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCGATGCAAGGATTCCACAAAGACAGCACTACACGAGTGGTGTTGGCTCCCGTAT<SEQ ID NO 15 CTx 15F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACCACGTGACCCATACGATACAACAAATAATTGCTCAAGAGCAGGTGTGACGGAT<SEQ ID NO 16 CTx 15R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTGAGCAATTATTTGTTGTATCGTATGGGTCACGTGGTGGTGTTGGCTCCCGTAT<SEQ ID NO 17 CTx 16F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATCCATAGCTCATCTATACCCTCTTCCGAGTCCCACCAGAGCAGGTGTGACGGAT<SEQ ID NO 18 CTx 16R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGGTGGGACTCGGAAGAGGGTATAGATGAGCTATGGATGGTGTTGGCTCCCGTAT<SEQ ID NO 19 CTx 17F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGACGCGGAACGACTCATCGCAAAATGTCGTGATGCAAGAGCAGGTGTGACGGAT<SEQ ID NO 20 CTx 17R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTGCATCACGACATTTTGCGATGAGTCGTTCCGCGTCTGGTGTTGGCTCCCGTAT<SEQ ID NO 21 CTx 18F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATGGTTAGGCTGCTCCATATATTCCCGCCCCGCACGTAGAGCAGGTGTGACGGAT<SEQ ID NO 22 CTx 18R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTACGTGCGGGGCGGGAATATATGGAGCAGCCTAACCATGGTGTTGGCTCCCGTAT<SEQ ID NO 23 CTx 38, 40F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATAGTGTTGGGCCAATACGGTAACGTGTCCTTGGAGAGCAGGTGTGACGGAT<SEQ ID NO 24 CTx 38, 40R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCCAAGGACACGTTACCGTATTGGCCCAACACTATGGTGTTGGCTCCCGTAT<SEQ ID NO 25 DP - 1 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATGCTGAACTAACAGATACAAGATACAGATCCGAGTTAGAGCAGGTGTGACGGAT<SEQ ID NO 26 DP - 1 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTAACTCGGATCTGTATCTTGTATCTGTTAGTTCAGCATGGTGTTGGCTCCCGTATATA<SEQ ID NO 27 DP - 1.1 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATGTCGCTGGTCACATCCCTAGTTAACAAACTTGGATAGAGCAGGTGTGACGGAT<SEQ ID NO 28 DP - 1.1 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTATCCAAGTTTGTTAACTAGGGATGTGACCAGCGACATGGTGTTGGCTCCCGTAT<SEQ ID NO 29 DP - 3 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATTGGCGTTACTAGAGGATTACTGAAAGCCATAAACTAGAGCAGGTGTGACGGAT<SEQ ID NO 30 DP - 3 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTAGTTTATGGCTTTCAGTAATCCTCTAGTAACGCCAATGGTGTTGGCTCCCGTAT<SEQ ID NO 31 DP - 4 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATCACTATAATTCCTTCGAACCTTACTTGTGTTAGCTAGAGCAGGTGTGACGGAT <SEQ ID NO 32 DP - 4 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTAGCTAACACAAGTAAGGTTCGAAGGAATTATAGTGATGGTGTTGGCTCCCGTAT<SEQ ID NO 33 DP - 5 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACTATCGACTTTTACATTCGTGTACGATTCCCGCTTCAGAGCAGGTGTGACGGAT<SEQ ID NO 34 DP - 5 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGAAGCGGGAATCGTACACGAATGTAAAAGTCGATAGTGGTGTTGGCTCCCGTAT<SEQ ID NO 35 DP - 6 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATCCCCTCGGGCGAGCTATACTAAACCAGATCCTAAGAGAGCAGGTGTGACGGAT <SEQ ID NO 36 DP - 6 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCTTAGGATCTGGTTTAGTATAGCTCGCCCGAGGGGATGGTGTTGGCTCCCGTAT<SEQ ID NO 37 DP - 7 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAAGCTACACAACGAGGCGTATAATCAGCATGTTGGATAGAGCAGGTGTGACGGAT<SEQ ID NO 38 DP - 7 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTATCCAACATGCTGATTATACGCCTCGTTGTGTAGCTTGGTGTTGGCTCCCGTAT<SEQ ID NO 39 DP - 8 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGGAAACTACTAAACGAACATGAGCTGTATCAAAAACAGAGCAGGTGTGACGGAT<SEQ ID NO 40 DP - 8 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGTTTTTGATACAGCTCATGTTCGTTTAGTAGTTTCCTGGTGTTGGCTCCCGTAT<SEQ ID NO 41 DP - 9 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATCCAGAGTAAACGATAAGGGGGAATCTCAATGAACCAGAGCAGGTGTGACGGAT<SEQ ID NO 42 DP - 9 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGGTTCATTGAGATTCCCCCTTATCGTTTACTCTGGATGGTGTTGGCTCCCGTAT<SEQ ID NO 43 DP - 10 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAATACTCTCAAAACCTAACAAGACAACCCGAGGGCCCAGAGCAGGTGTGACGGAT<SEQ ID NO 44 DP - 10 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGGGCCCTCGGGTTGTCTTGTTAGGTTTTGAGAGTATTGGTGTTGGCTCCCGTAT<SEQ ID NO 45 DP - 11 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATGAGACTGGGTCGATCCAGGACATACATTTGTACTAAGAGCAGGTGTGACGGAT<SEQ ID NO 46 DP - 11 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTAGTACAAATGTATGTCCTGGATCGACCCAGTCTCATGGTGTTGGCTCCCGTAT<SEQ ID NO 47 DP - 12 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGAGCCAGAATAATGGCCCCCTTTACGAGACGACTGTAGAGCAGGTGTGACGGAT<SEQ ID NO 48 DP - 12 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTACAGTCGTCTCGTAAAGGGGGCCATTATTCTGGCTCTGGTGTTGGCTCCCGTAT<SEQ ID NO 49 DP - 13 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATCAGGCCGAAATGTATACGAAGGTAAGCGATAAAGTAGAGCAGGTGTGACGGAT<SEQ ID NO 50 DP - 13 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTACTTTATCGCTTACCTTCGTATACATTTCGGCCTGATGGTGTTGGCTCCCGTAT<SEQ ID NO 51 DP - 14 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGTCGTACGACACCCATCCAAGACTTTATTCCGCCTAAGAGCAGGTGTGACGGAT<SEQ ID NO 52 DP - 14 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTAGGCGGAATAAAGTCTTGGATGGGTGTCGTACGACTGGTGTTGGCTCCCGTAT<SEQ ID NO 53 DP - 15 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACGGTACAAACTCTCAACAAGCTACCACTTTAGTCCAAGAGCAGGTGTGACGGAT<SEQ ID NO 54 DP - 15 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTGGACTAAAGTGGTAGCTTGTTGAGAGTTTGTACCGTGGTGTTGGCTCCCGTAT<SEQ ID NO 55 DP - 16 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACTCGTTTGGCCCACGAGTCAATCATATATCAGCTAAAGAGCAGGTGTGACGGAT<SEQ ID NO 56 DP - 16 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTTAGCTGATATATGATTGACTCGTGGGCCAAACGAGTGGTGTTGGCTCCCGTAT<SEQ ID NO 57 DP - 17 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATTATTATCAAGACGCTATCTACAGAGATTCACGGACAGAGCAGGTGTGACGGAT<SEQ ID NO 58 DP - 17 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGTCCGTGAATCTCTGTAGATAGCGTCTTGATAATAATGGTGTTGGCTCCCGTAT<SEQ ID NO 59 DP - 18 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGTGCGTGCGTGGCGACGGTACTACTGACTATGTCGTAGAGCAGGTGTGACGGAT<SEQ ID NO 60 DP - 18 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTACGACATAGTCAGTAGTACCGTCGCCACGCACGCACTGGTGTTGGCTCCCGTAT<SEQ ID NO 61 DP - 19 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATGCCATTCCTGTGTTAGTCTGTCCGTTCGACAAGGCAGAGCAGGTGTGACGGAT<SEQ ID NO 62 DP - 19 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGCCTTGTCGAACGGACAGACTAACACAGGAATGGCATGGTGTTGGCTCCCGTAT<SEQ ID NO 63 DP - 20 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGAGTGTTGGCGATAAACACAATGACCCACAGCCGGAAGAGCAGGTGTGACGGAT<SEQ ID NO 64 DP - 20 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTCCGGCTGTGGGTCATTGTGTTTATCGCCAACACTCTGGTGTTGGCTCCCGTAT<SEQ ID NO 65 DP - 22 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATTCTGGTGCGCGTGCAATGAGAGAAATGGCTCGTACAGAGCAGGTGTGACGGAT<SEQ ID NO 66 P - 22 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGTACGAGCCATTTCTCTCATTGCACGCGCACCAGAATGGTGTTGGCTCCCGTAT<SEQ ID NO 67 DP - 22 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACCGCGTTAAAGAGGCGTACGATGTCTCAGTCTCGCCAGAGCAGGTGTGACGGAT<SEQ ID NO 68 DP - 22 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGGCGAGACTGAGACATCGTACGCCTCTTTAACGCGGTGGTGTTGGCTCCCGTAT<SEQ ID NO 69 DP - 23 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATTCTGGTGCGCGTGCAATGAGAGAAATGGCTCGTACAGAGCAGGTGTGACGGAT<SEQ ID NO 70 DP - 23 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGTACGAGCCATTTCTCTCATTGCACGCGCACCAGAATGGTGTTGGCTCCCGTAT<SEQ ID NO 71 DP - 23 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACCGCGTTAAAGAGGCGTACGATGTCTCAGTCTCGCCAGAGCAGGTGTGACGGAT<SEQ ID NO 72 DP - 23 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGGCGAGACTGAGACATCGTACGCCTCTTTAACGCGGTGGTGTTGGCTCCCGTAT<SEQ ID NO 73 DP - 24 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATCTAACTGATGTGTTGCGAAGGGTCTGCTGTGTGATAGAGCAGGTGTGACGGAT<SEQ ID NO 74 DP - 24 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTATCACACAGCAGACCCTTCGCAACACATCAGTTAGATGGTGTTGGCTCCCGTAT<SEQ ID NO 75 DP - 27 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGGCGGGAGAATAGATAGAGTTAGTCGTAGTTAGAGCAGAGCAGGTGTGACGGAT<SEQ ID NO 76 DP - 27 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGCTCTAACTACGACTAACTCTATCTATTCTCCCGCCTGGTGTTGGCTCCCGTAT<SEQ ID NO 77 DP - 28 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGAAGAACCGCTAAAGCCTATGAGGAAAGGATCATGCAGAGCAGGTGTGACGGAT<SEQ ID NO 78 DP - 28 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGCATGATCCTTTCCTCATAGGCTTTAGCGGTTCTTCTGGTGTTGGCTCCCGTAT<SEQ ID NO 79 DP - 30 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGCCACGTCGAACCGGGTGTCCATATACGTAATATGCAGAGCAGGTGTGACGGAT<SEQ ID NO 80 DP - 30 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGCATATTACGTATATGGACACCCGGTTCGACGTGGCTGGTGTTGGCTCCCGTAT<SEQ ID NO 81 DP - 31 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATGCCATGTACCGGTACCTACTCTATCAGGATATAGGAGAGCAGGTGTGACGGAT<SEQ ID NO 82 DP - 31 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCCTATATCCTGATAGAGTAGGTACCGGTACATGGCATGGTGTTGGCTCCCGTAT<SEQ ID NO 83 DP - 32 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGAGTATTCCGCTCACCTATCGCCACCATGTACACCAAGAGCAGGTGTGACGGAT<SEQ ID NO 84 DP - 32 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTGGTGTACATGGTGGCGATAGGTGAGCGGAATACTCTGGTGTTGGCTCCCGTAT<SEQ ID NO 85 DP - 33 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAACATTGAGAGTGTGGACATAGTGGAACGCGAACCTGAGAGCAGGTGTGACGGAT<SEQ ID NO 86 DP - 33 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCAGGTTCGCGTTCCACTATGTCCACACTCTCAATGTTGGTGTTGGCTCCCGTAT<SEQ ID NO 87 DP - 34 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAAGCGACAAGGAAGAATTATCAAGGTACGAACCGGATAGAGCAGGTGTGACGGAT<SEQ ID NO 88 DP - 34 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTATCCGGTTCGTACCTTGATAATTCTTCCTTGTCGCTTGGTGTTGGCTCCCGTAT<SEQ ID NO 89 DP - 35 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATGTCATCATATACCAACACTGGCGCGGATAGTCCAGAGAGCAGGTGTGACGGAT<SEQ ID NO 90 DP - 35 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCTGGACTATCCGCGCCAGTGTTGGTATATGATGACATGGTGTTGGCTCCCGTAT<SEQ ID NO 91 DP - 36 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGCCTCGTGATTTGATGAAGTTTCTTGATCTGCACGTAGAGCAGGTGTGACGGAT<SEQ ID NO 92 DP - 36 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTACGTGCAGATCAAGAAACTTCATCAAATCACGAGGCTGGTGTTGGCTCCCGTAT<SEQ ID NO 93 DP - 37 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATCGATGAACGGCTCACCCTCGTCCCTATATAACACTAGAGCAGGTGTGACGGAT<SEQ ID NO 94 DP - 37 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTAGTGTTATATAGGGACGAGGGTGAGCCGTTCATCGATGGTGTTGGCTCCCGTAT<SEQ ID NO 95 DP - 38 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAAAGGACACAAGAAGCTTGAATCTCCAGTTAGTGGGGAGAGCAGGTGTGACGGAT<SEQ ID NO 96 DP - 38 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCCCCACTAACTGGAGATTCAAGCTTCTTGTGTCCTTTGGTGTTGGCTCCCGTAT<SEQ ID NO 97 DP - 39 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACGCTCCCCGAGATCACGTACGCTCGCCCCAGACTGGAGAGCAGGTGTGACGGAT<SEQ ID NO 98 DP - 39 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCCAGTCTGGGGCGAGCGTACGTGATCTCGGGGAGCGTGGTGTTGGCTCCCGTAT<SEQ ID NO 99 DP - 40 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATGGCTCACCAGGACCATTATTTTCAGCTCCCCCGCCAGAGCAGGTGTGACGGAT<SEQ ID NO 100 DP - 40 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGGCGGGGGAGCTGAAAATAATGGTCCTGGTGAGCCATGGTGTTGGCTCCCGTAT<SEQ ID NO 101 PY - 1 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGTGCACCAAATAAAAAGCTGTCCCAGACTCGAGCGAAGAGCAGGTGTGACGGAT<SEQ ID NO 102 PY - 1 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTCGCTCGAGTCTGGGACAGCTTTTTATTTGGTGCACTGGTGTTGGCTCCCGTAT<SEQ ID NO 103 PY - 2 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAATCGTGTCACAATGGCATATCCTACGTCATAAGCCAAGAGCAGGTGTGACGGAT<SEQ ID NO 104 PY - 2 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTGGCTTATGACGTAGGATATGCCATTGTGACACGATTGGTGTTGGCTCCCGTAT<SEQ ID NO 105 PY - 4 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATAATACCAGCCGACAGCCTTGGTGCTATGATTTGACAGAGCAGGTGTGACGGAT<SEQ ID NO 106 PY - 4 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGTCAAATCATAGCACCAAGGCTGTCGGCTGGTATTATGGTGTTGGCTCCCGTAT<SEQ ID NO 107 PY - 5 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATCGAGTGCGTGGAACTCAAGGGCACAATAGCTACACAGAGCAGGTGTGACGGAT<SEQ ID NO 108 PY - 5 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGTGTAGCTATTGTGCCCTTGAGTTCCACGCACTCGATGGTGTTGGCTCCCGTAT<SEQ ID NO 109 PY - 7 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACATAGTCCCTGTCGCACCCCTCCCGTGACCGTTATCAGAGCAGGTGTGACGGAT<SEQ ID NO 110 PY - 7 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGATAACGGTCACGGGAGGGGTGCGACAGGGACTATGTGGTGTTGGCTCCCGTAT<SEQ ID NO 111 PY - 7.1 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGGCGTTCTAGAGACCACTCTTAATAACCTTGATGTGAGAGCAGGTGTGACGGAT <SEQ ID NO 112 PY - 7.1 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCACATCAAGGTTATTAAGAGTGGTCTCTAGAACGCCTGGTGTTGGCTCCCGTAT<SEQ ID NO 113 PY - 8 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGTTTCTCAGTATATAAGATATTTCATCGCAGGTAGAAGAGCAGGTGTGACGGAT<SEQ ID NO 114 PY - 8 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTCTACCTGCGATGAAATATCTTATATACTGAGAAACTGGTGTTGGCTCCCGTAT<SEQ ID NO 115 PY - 9 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAATGTGACAGTCGCGACTCCTGTCGTTTGCATAGGGTAGAGCAGGTGTGACGGAT<SEQ ID NO 116 PY - 9 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTACCCTATGCAAACGACAGGAGTCGCGACTGTCACATTGGTGTTGGCTCCCGTAT<SEQ ID NO 117 PY - 10 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAAAAAATCAACATGGTGAAACATTCGAATGCAGTTGAAGAGCAGGTGTGACGGAT<SEQ ID NO 118 PY - 10 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTCAACTGCATTCGAATGTTTCACCATGTTGATTTTTTGGTGTTGGCTCCCGTAT<SEQ ID NO 119 PY - 11 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATGCGCGGCTCATAGACTGTAACCCGGATGGGAACCTAGAGCAGGTGTGACGGAT<SEQ ID NO 120 PY - 11 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTAGGTTCCCATCCGGGTTACAGTCTATGAGCCGCGCATGGTGTTGGCTCCCGTAT<SEQ ID NO 121 PY - 12 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAAGTCCCGTTACCAAACAGAACCATGGAGAGCGATGGAGAGCAGGTGTGACGGAT<SEQ ID NO 122 PY - 12 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCCATCGCTCTCCATGGTTCTGTTTGGTAACGGGACTTGGTGTTGGCTCCCGTAT <SEQ ID NO 123 PY - 13 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATTGACCCGAGACTCCAGCTGAGTGACACCTGATGTGAGAGCAGGTGTGACGGAT<SEQ ID NO 124 PY - 13 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCACATCAGGTGTCACTCAGCTGGAGTCTCGGGTCAATGGTGTTGGCTCCCGTAT<SEQ ID NO 125 PY - 14 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGTGACACCAAACCATGCTCAGGCCATTCGGTTATATAGAGCAGGTGTGACGGAT<SEQ ID NO 126 PY - 14 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTATATAACCGAATGGCCTGAGCATGGTTTGGTGTCACTGGTGTTGGCTCCCGTAT<SEQ ID NO 127 PY - 15 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGCCAACGGACACCAGGTTGATCAATCCCCAGTCCTGAGAGCAGGTGTGACGGAT<SEQ ID NO 128 PY - 15 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCAGGACTGGGGATTGATCAACCTGGTGTCCGTTGGCTGGTGTTGGCTCCCGTAT<SEQ ID NO 129 PY - 16 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGCCCTACCGTACCCCCTCAAGACAGAACCTGCATCAAGAGCAGGTGTGACGGAT<SEQ ID NO 130 PY - 16 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTGATGCAGGTTCTGTCTTGAGGGGGTACGGTAGGGCTGGTGTTGGCTCCCGTAT<SEQ ID NO 131 PY - 17 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACTAGACAAGGTCAAACCGCATATGGACCCGTGCTATAGAGCAGGTGTGACGGAT<SEQ ID NO 132 PY - 17 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTATAGCACGGGTCCATATGCGGTTTGACCTTGTCTAGTGGTGTTGGCTCCCGTAT<SEQ ID NO 133 PY - 18 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACAACATGAGCTGAATCTGTCCCTAATGCGTGTGCATAGAGCAGGTGTGACGGAT<SEQ ID NO 134 PY - 18 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTATGCACACGCATTAGGGACAGATTCAGCTCATGTTGTGGTGTTGGCTCCCGTAT<SEQ ID NO 135 PY - 19 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACGGTGAAGCATGGCAATATTAACCATGATCACCTTCAGAGCAGGTGTGACGGAT<SEQ ID NO 136 PY - 19 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGAAGGTGATCATGGTTAATATTGCCATGCTTCACCGTGGTGTTGGCTCCCGTAT<SEQ ID NO 137 PY - 20 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACCACTTGTCACGACCGTGTCTCTGTGGCGCTTGGGGAGAGCAGGTGTGACGGAT<SEQ ID NO 138 PY - 20 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCCCCAAGCGCCACAGAGACACGGTCGTGACAAGTGGTGGTGTTGGCTCCCGTAT<SEQ ID NO 139 ProCathep K 1F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATATAGCCGCGCCTGTGAGTTTTGTGGGAGCAAGAGTAGAGCAGGTGTGACGGAT<SEQ ID NO 140 ProCathep K 1R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTACTCTTGCTCCCACAAAACTCACAGGCGCGGCTATATGGTGTTGGCTCCCGTAT<SEQ ID NO 141 ProCathep K 2F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGCTACAGTGTCAGACGGTTCCACCTTAACCTCGTCAAGAGCAGGTGTGACGGAT<SEQ ID NO 142 ProCathep K 2R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTGACGAGGTTAAGGTGGAACCGTCTGACACTGTAGCTGGTGTTGGCTCCCGTAT<SEQ ID NO 143 ProCathep K 3F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATTGACTAAGCGATTAGTCCCACAGGTGACCGGGGAGAGAGCAGGTGTGACGGAT<SEQ ID NO 144 ProCathep K 3R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCTTCCCGGNCTCCTGTGTGATTAATCTGTTATTCTATGGTGTTGGCTCCCGTAT<SEQ ID NO 145 ProCathep K 4F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAATTCTAACACAGGTTTCTCCGTTTCGTTAGCTGCTAAGAGCAGGTGTGACGGAT <SEQ ID NO 146 ProCathep K 4R; DNA; SYNTHETICOLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTAGCAGCTAACGAAACGGAGAAACCTGTGTTAGAATTGGTGTTGGCTCCCGTAT<SEQ ID NO 147 Procathep K 6F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACTCATCCCGTTGGAACACTTTAATATGGCCCACTCTAGAGCAGGTGTGACGGAT<SEQ ID NO 148 Procathep K 6R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTAGAGTGGGCCATATTAAAGTGTTCCAACGGGATGAGTGGTGTTGGCTCCCGTAT<SEQ ID NO 149 HP - 1/3 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACTACTGTGCAGATCCAGCATCTACGGTGAAATTTGCAGAGCAGGTGTGACGGAT<SEQ ID NO 150 HP - 1/3 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGCAAATTTCACCGTAGATGCTGGATCTGCACAGTAGTGGTGTTGGCTCCCGTAT<SEQ ID NO 151 HP - 2/4 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATGCGGAAAGCCCATACCAACCCAGAAGCCAGCGCTAAGAGCAGGTGTGACGGAT<SEQ ID NO 152 HP - 2/4 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTAGCGCTGGCTTCTGGGTTGGTATGGGCTTTCCGCATGGTGTTGGCTCCCGTAT<SEQ ID NO 153 HP - 5 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGCCAACTAGCCTGAAACCCATAATTATACAGCTTAGAGAGCAGGTGTGACGGAT<SEQ ID NO 154 HP - 5 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCTAAGCTGTATAATTATGGGTTTCAGGCTAGTTGGCTGGTGTTGGCTCCCGTAT<SEQ ID NO 155 HP - 6 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACTGTATCCGTTGATGACAAACAGTCGCAGCCCACTTAGAGCAGGTGTGACGGAT<SEQ ID NO 156 HP - 6 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCCTCGACTCGATTTCACTTAGTCTAACACTAATTGGTGGTGTTGGCTCCCGTAT<SEQ ID NO 157 HP - 7 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAAGGTAATGAAGGGGGAAAATGGAGTTTTGCCCTTAAAGAGCAGGTGTGACGGAT<SEQ ID NO 158 HP - 7 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTTAAGGGCAAAACTCCATTTTCCCCCTTCATTACCTTGGTGTTGGCTCCCGTAT<SEQ ID NO 159 HP - 8 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAAGCTCGTAGAAGCATCTTACGCGGCGCCCTTGCACCAGAGCAGGTGTGACGGAT<SEQ ID NO 160 HP - 8 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGGTGCAAGGGCGCCGCGTAAGATGCTTCTACGAGCTTGGTGTTGGCTCCCGTAT<SEQ ID NO 161 HP - 9 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACGATCATTGACATACTTCTCTATCCCGTCTGTCTGTAGAGCAGGTGTGACGGAT <SEQ ID NO 162 HP - 9 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTACAGACAGACGGGATAGAGAAGTATGTCAATGATCGTGGTGTTGGCTCCCGTAT<SEQ ID NO 163 HP - 10 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACCACAGAGTCTACCCAAGGCAGGCTGTCAATCAACAAGAGCAGGTGTGACGGAT<SEQ ID NO 164 HP - 10 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTGTTGATTGACAGCCTGCCTTGGGTAGACTCTGTGGTGGTGTTGGCTCCCGTAT<SEQ ID NO 165 HP - 11 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGGCTACGACAAAGGCTATGACATGAATGGGTCAACTAGAGCAGGTGTGACGGAT<SEQ ID NO 166 HP - 11 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTAGTTGACCCATTCATGTCATAGCCTTTGTCGTAGCCTGGTGTTGGCTCCCGTAT<SEQ ID NO 167 HP - 12 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGGGCCGGAGGGTTCTTCTTGAGCCTTTTCGCCAGGCAGAGCAGGTGTGACGGAT<SEQ ID NO 168 HP - 12 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGCCTGGCGAAAAGGCTCAAGAAGAACCCTCCGGCCCTGGTGTTGGCTCCCGTAT<SEQ ID NO 169 HP - 13 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAAATGTCTTGGAAGGCAGATATCGGAACGAGTGGACCAGAGCAGGTGTGACGGAT<SEQ ID NO 170 HP - 13 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGGTCCACTCGTTCCGATATCTGCCTTCCAAGACATTTGGTGTTGGCTCCCGTAT<SEQ ID NO 171 HP - 14 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGACACTCAGGTATGGAGCACTCGATCCACGCGTGTGAGAGCAGGTGTGACGGAT<SEQ ID NO 172 HP - 14 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCACACGCGTGGATCGAGTGCTCCATACCTGAGTGTCTGGTGTTGGCTCCCGTAT<SEQ ID NO 173 HP - 15 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATCCGCGACCAGAATCTGTAAAGGCGTTAGATATGCCAGAGCAGGTGTGACGGAT<SEQ ID NO 174 HP - 15 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGGCATATCTAACGCCTTTACAGATTCTGGTCGCGGATGGTGTTGGCTCCCGTAT<SEQ ID NO 175 HP - 16 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACTCAACGTAACGGGTGGAGACCCTCACATCGATATGAGAGCAGGTGTGACGGAT<SEQ ID NO 176 HP - 16 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCATATCGATGTGAGGGTCTCCACCCGTTACGTTGAGTGGTGTTGGCTCCCGTAT<SEQ ID NO 177 HP - 18 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGATGGTGACCGGATTACGAGAACCAGAGCTGATAGAAGAGCAGGTGTGACGGAT<SEQ ID NO 178 HP - 18 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTCTATCAGCTCTGGTTCTCGTAATCCGGTCACCATCTGGTGTTGGCTCCCGTAT<SEQ ID NO 179 HP - 19 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAAACCAGGGAATACACAGCAAAACTACGGTGTCCTGTAGAGCAGGTGTGACGGAT <SEQ ID NO 180 HP - 19 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTACAGGACACCGTAGTTTTGCTGTGTATTCCCTGGTTTGGTGTTGGCTCCCGTAT<SEQ ID NO 181 HP - 20 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGCCGATAAAGAACGCAGCTAATTTGCTCTCCCGAGCAGAGCAGGTGTGACGGAT<SEQ ID NO 182 HP - 20 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGCTCGGGAGAGCAAATTAGCTGCGTTCTTTATCGGCTGGTGTTGGCTCCCGTAT<SEQ ID NO 183 HP - 24 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGCATATGTAGTGAAGCGACATACACCGGGGCAACGTAGAGCAGGTGTGACGGAT<SEQ ID NO 184 HP - 24 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTACGTTGCCCCGGTGTATGTCGCTTCACTACATATGCTGGTGTTGGCTCCCGTAT<SEQ ID NO 185 HP - 25/27 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACCGAACTAAGAGGAAAGTCTCGGAGTGCGGCTAGTTAGAGCAGGTGTGACGGAT <SEQ ID NO 186 HP - 25/27 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTAACTAGCCGCACTCCGAGACTTTCCTCTTAGTTCGGTGGTGTTGGCTCCCGTAT<SEQ ID NO 187 HP - 26 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAAGGCCACCCAGTTAATGCAGTCTCGTTATGTTCTGTAGAGCAGGTGTGACGGAT<SEQ ID NO 188 HP - 26 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTACAGAACATAACGAGACTGCATTAACTGGGTGGCCTTGGTGTTGGCTCCCGTAT<SEQ ID NO 189 HP - 29 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAATACCATACCTGACTTATGACCTGATCATACCAGTGAGAGCAGGTGTGACGGAT<SEQ ID NO 190 HP - 29 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCACTGGTATGATCAGGTCATAAGTCAGGTATGGTATTGGTGTTGGCTCCCGTAT<SEQ ID NO 191 HP - 32 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAGCACCACAGATTCTTCAACTTTGCTGCCATATTCCAACAACAGAGCAGGCGTGACGGAT<SEQ ID NO 192 HP - 32 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACGCCTGCTCTGTTGTTGGAATATGGCAGCAAAGTTGAAGAATCTGTGGTGCTGGCTCCCGTAT<SEQ ID NO 193 HP - 33 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACATGCCATAATTGGACCCTCATCGCCCCGTCGTCCCAGAGCAGGTGTGACGGAT<SEQ ID NO 194 HP - 33 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGGGACGACGGGGCGATGAGGGTCCAATTATGGCATGTGGTGTTGGCTCCCGTAT<SEQ ID NO 195 HP - 35 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAAACCGCACCAGTCACACACCAGTTCGCCTCCATGTTAGAGCAGGTGTGACGGAT<SEQ ID NO 196 HP - 35 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTAACATGGAGGCGAACTGGTGTGTGACTGGTGCGGTTTGGTGTTGGCTCCCGTAT<SEQ ID NO 197 HP - 36 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATTTTACAGTACTAAAGTATGTGATATGCCGCGCCGGAGAGCAGGTGTGACGGAT<SEQ ID NO 198 HP - 36 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCCGGCGCGGCATATCACATACTTTAGTACTGTAAAATGGTGTTGGCTCCCGTAT<SEQ ID NO 199 HP - 39 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAAAAGAACGCACTACTTTCGGAATCGAATCTATCCCCAGAGCAGGTGTGACGGAT<SEQ ID NO 200 HP - 39 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGGGGATAGATTCGATTCCGAAAGTAGTGCGTTCTTTTGGTGTTGGCTCCCGTAT<SEQ ID NO 201 Hydroxylys 9R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTAGACGAATATTGTATCCTCATTAGATCAAAAACGGGTGGTGTTGGCTCCCGTAT<SEQ ID NO 202 HydroxylyS 10F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGCTTTTCCTAGAATGATTTTCTTTAGCTACCTGAGAAGAGCAGGTGTGACGGAT<SEQ ID NO 203 Hydroxylys 10R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTCTCAGGTAGCTAAAGAAAATCATTCTAGGAAAAGCTGGTGTTGGCTCCCGTAT<SEQ ID NO 204 Hydroxyly<S 5F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACGCTTAGATATTATCCTTGTCCAGAGCAGGTGTGACGGAT <SEQ ID NO205 Hydroxylys 5R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGGACAAGGATAATATCTAAGCGTGGTGTTGGCTCCCGTAT> <SEQ ID NO206 Hydroxylys 6F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ACACGGGAGCCAACACCATCCATAGCTCATCTATACCCTCTTCCGAGTCCCACCAGAGCAGGTGTGACGGAT<SEQ ID NO 207 Hydroxylys 6R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGGTGGGACTCGGAAGAGGGTATAGATGAGCTATGGATGGTGTTGGCTCCCGTGT<SEQ ID NO 208 Hydroxylys 7F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACCCTACACCAGCGCCCTACACTTTTGTAGCACTTCGAGAGCAGGTGTGACGGAT<SEQ ID NO 209 Hydroxylys 7R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCGAAGTGCTACAAAAGTGTAGGGCGCTGGTGTAGGGTGGTGTTGGCTCCCGTAT<SEQ ID NO 210 Hydroxylys 8F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATAGTGTTGGGCCAATACGGTAACGTGTCCTTGGAGAGCAGGTGTGACGGAT<SEQ ID NO 211 Hydroxylys 8R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCCAAGGACACGTTACCGTATTGGCCCAACACTATGGTGTTGGCTCCCGTAT<SEQ ID NO 212 Hydroxylys 9F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACCCGTTTTTGATCTAATGAGGATAGAATATTCGTCTAGAGCAGGTGTGACGGAT<SEQ ID NO 213 NTx 10F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACTATCAATTTGTTGGCGACACTTCAACCCACACGTTAGAGCAGGTGTGACGGAT<SEQ ID NO 214 NTx 10R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTAACGTGTGGGTTGAAGTGTCGCCAACAAATTGATAGTGGTGTTGGCTCCCGTAT<SEQ ID NO 215 NTx 11F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATCAGCATGGGTTAGAGCTGGGGGAAATATTTGGTCGAGAGCAGGTGTGACGGAT<SEQ ID NO 216 NTx 11R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCGACCAAATATTTCCCCCAGCTCTAACCCATGCTGATGGTGTTGGCTCCCGTAT<SEQ ID NO 217 NTx 12F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATAGTGTTGGGCCAATACGGTAACGTGTCCTTGGAGAGCAGGTGTGACGGAT<SEQ ID NO 218 NTx 12R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCCAAGGACACGTTACCGTATTGGCCCAACACTATGGTGTTGGCTCCCGTAT<SEQ ID NO 219 NTx 13F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAACAAAACAACAGGAATATCGTTCCCAAGCGGACCCCAGAGCAGGTGTGACGGAT<SEQ ID NO 220 NTx 13R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGGGGTCCGCTTGGGAACGATATTCCTGTTGTTTTGTTGGTGTTGGCTCCCGTAT<SEQ ID NO 221 NTx 14F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATACAAAGTGTTGTTAGATTTAACCCATGTTGCCATCAGAGCAGGTGTGACGGAT<SEQ ID NO 222 NTx 14R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGATGGCAACATGGGTTAAATCTAACAACACTTTGTATGGTGTTGGCTCCCGTAT<SEQ ID NO 223 NTx 15F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAAGGGTGTTCACACTGGCAGGCGACGCCCTCGTGTTGAGAGCAGGTGTGACGGAT<SEQ ID NO 224 NTx 15R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCAACACGAGGGCGTCGCCTGCCAGTGTGAACACCCTTGGTGTTGGCTCCCGTATN <SEQ ID NO 225 Tx 2F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACAATAGTCGATTAGTAATGATCCACACATTGGTCGGAGAGCAGGTGTGACGGAT<SEQ ID NO 226 NTx 2R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCCGACCAATGTGTGGATCATTACTAATCGACTATTGTGGTGTTGGCTCCCGTAT<SEQ ID NO 227 NTx 4F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATAGTTTTGGGCCAATACGGTAACGTGTCCTTGGAGAGCAGGTGTGACGGAT<SEQ ID NO 228 NTx 4R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCCAAGGACACGTTACCGTATTGGCCCAAAACTATGGTGTTGGCTCCCGTAT<SEQ ID NO 229 NTx 8F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATAGTGCTGGACCAATACGGTAACGTGTCCTTGGAGAGCAGGTGTGACGGAT<SEQ ID NO 230 NTx 8R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCCAAGGACACGTTACCGTATTGGTCCAGCACTATGGTGTTGGCTCCCGTAT<SEQ ID NO 231 Osteocalcin 2F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACGATTAGCAATGAATTATCTACAGAGCAGGTGTGACGGAT <SEQ ID NO232 Osteocalcin 2R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGTAGATAATTCATTGCTAATCGTGGTGTTGGCTCCCGTAT <SEQ ID NO233 Osteocalcin 4F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAATTCTAACACAGGTTTCTCCGTTTCGTTAGCTGCTAAGAGCAGGTGTGACGGAT<SEQ ID NO 234 Osteocalcin 4R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTAGCAGCTAACGAAACGGAGAAACCTGTGTTAGAATTGGTGTTGGCTCCCGTAT<SEQ ID NO 235 Osteocalcin 7F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATTCTATCGTTCCGGACGCTTATGCCTTGCCATCTACAGAGCAGGTGTGACGGAT<SEQ ID NO 236 Osteocalcin 7R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGTAGATGGCAAGGCATAAGCGTCCGGAACGATAGAATGGTGTTGGCTCCCGTAT<SEQ ID NO 237 Osteocalcin 8F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAACTGACTCAGTCTGCTGGTGGGCTATATTTTTGCGGAGAGCAGGTGTGACGGAT<SEQ ID NO 238 Osteocalcin 8R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCCGCAAAAATATAGCCCACCAGCAGACTGAGTCAGTTGGTGTTGGCTCCCGTAT<SEQ ID NO 239 Cr - 2 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGACCGGGCGGTAAAATAACAAATTACATCCCCACCGAGAGCAGGTGTGACGGAT<SEQ ID NO 240 Cr - 2 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCGGTGGGGATGTAATTTGTTATTTTACCGCCCGGTCTGGTGTTGGCTCCCGTAT<SEQ ID NO 241 Cr - 3 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAATGACCATATCAAACCACACCGGCCCCCCACTGATGAGAGCAGGTGTGACGGAT<SEQ ID NO 242 Cr - 3 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCATCAGTGGGGGGCCGGTGTGGTTTGATATGGTCATTGGTGTTGGCTCCCGTAT<SEQ ID NO 243 Cr - 4 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAATGACCATATCAAACCACACCGGCCCCCCACTGATGAGAGCAGGTGTGACGGAT<SEQ ID NO 244 Cr - 4 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCATCAGTGGGGGGCCGGTGTGGTTTGATATGGTCATTGGTGTTGGCTCCCGTAT<SEQ ID NO 245 Cr - 7 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACTCAAGTCCAGATCACACTCGTGCTGCTACCGGTTCAGAGCAGGTGTGACGGAT<SEQ ID NO 246 Cr - 7 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGAACCGGTAGCAGCACGAGTGTGATCTGGACTTGAGTGGTGTTGGCTCCCGTAT<SEQ ID NO 247 Cr - 8 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATTTCTAACTAATCGAGTCGGTACCACTGGGCCCCTGAGAGCAGGTGTGACGGAT<SEQ ID NO 248 Cr - 8 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCAGGGGCCCAGTGGTACCGACTCGATTAGTTAGAAATGGTGTTGGCTCCCGTAT<SEQ ID NO 249 Cr - 8.1 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATGGCTAGGAAATAATGTCCATCGGCACATCCTCCCGAGAGCAGGTGTGACGGAT<SEQ ID NO 250 Cr - 8.1 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCGGGAGGATGTGCCGATGGACATTATTTCCTAGCCATGGTGTTGGCTCCCGTAT<SEQ ID NO 251 Cr - 10 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAACCGTACAAACAAGCTAGTGTGGTTAATACTGCATAAGAGCAGGTGTGACGGAT<SEQ ID NO 252 Cr - 10 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTATGCAGTATTAACCACACTAGCTTGTTTGTACGGTTGGTGTTGGCTCCCGTAT<SEQ ID NO 253 Cr - 11 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGAGGCTACCGGTAAATGGGATATCATTGCGTTTGCAAGAGCAGGTGTGACGGAT<SEQ ID NO 254 Cr - 11 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTGCAAACGCAATGATATCCCATTTACCGGTAGCCTCTGGTGTTGGCTCCCGTAT<SEQ ID NO 255 Cr - 12 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACTCAAAGGGTTACCAATCCGTTGGACACAGTACTGTAGAGCAGGTGTGACGGAT<SEQ ID NO 256 Cr - 12 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTACAGTACTGTGTCCAACGGATTGGTAACCCTTTGAGTGGTGTTGGCTCCCGTAT<SEQ ID NO 257 Cr - 13 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATGAACATACAAGAGGTAGACCTGGTAGTCGTATTCTAGAGCAGGTGTGACGGAT<SEQ ID NO 258 Cr - 13 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTAGAATACGACTACCAGGTCTACCTCTTGTATGTTCATGGTGTTGGCTCCCGTAT<SEQ ID NO 259 Cr - 14 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATCTGAGCCGTAATTGGTTATTTTCCAGTGAAGTGCGAGAGCAGGTGTGACGGAT<SEQ ID NO 260 Cr - 14 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCGCACTTCACTGGAAAATAACCAATTACGGCTCAGATGGTGTTGGCTCCCGTAT<SEQ ID NO 261 Cr - 15 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATGACTACGTGGGCAAGACATCCCGCGCGTCCATCCCAGAGCAGGTGTGACGGAT<SEQ ID NO 262 Cr - 15 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGGGATGGACGCGCGGGATGTCTTGCCCACGTAGTCATGGTGTTGGCTCCCGTAT<SEQ ID NO 263 Cr - 15.1 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAACATGGCGTGGCAGGTAATCTAACCTCCCTACCCAAGAGCAGGTGTGACGGAT<SEQ ID NO 264 Cr 15.1 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTGGGTAGGGAGGTTAGATTACCTGCCACGCCATGTTGGTGTTGGCTCCCGTAT<SEQ ID NO 265 Cr - 16 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACACGACCCAAGGAATTGGAAAAACACCGACATTCCAAGAGCAGGTGTGACGGAT<SEQ ID NO 266 Cr - 16 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTGGAATGTCGGTGTTTTTCCAATTCCTTGGGTCGTGTGGTGTTGGCTCCCGTAT<SEQ ID NO 267 Cr - 18 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAAGACTGATAACCTTACGTCCAGTAGGGGCAAGCTATAGAGCAGGTGTGACGGAT<SEQ ID NO 268 Cr - 18 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTATAGCTTGCCCCTACTGGACGTAAGGTTATCAGTCTTGGTGTTGGCTCCCGTAT<SEQ ID NO 269 Cr - 19 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAATAACCGTTTTCGGCCATGAGAATACTGTCACTTACAGAGCAGGTGTGACGGAT<SEQ ID NO 270 Cr - 19 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGTAAGTGACAGTATTCTCATGGCCGAAAACGGTTATTGGTGTTGGCTCCCGTAT<SEQ ID NO 271 Cr - 20 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAAGACGAATAGCTCACTACCTCGTGAACTATCCCCTGAGAGCAGGTGTGACGGAT<SEQ ID NO 272 Cr - 20 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCAGGGGATAGTTCACGAGGTAGTGAGCTATTCGTCTTGGTGTTGGCTCCCGTAT<SEQ ID NO 273 Cr - 21 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATACAGGATCTATTCCCAGAAGAGTTGGCATATACCAAGAGCAGGTGTGACGGAT<SEQ ID NO 274 Cr - 21 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTGGTATATGCCAACTCTTCTGGGAATAGATCCTGTATGGTGTTGGCTCCCGTAT<SEQ ID NO 275 Cr - 22 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATGGAGAACATTTCCATGTTGGCGACCATGGGCCTCGAGAGCAGGTGTGACGGAT<SEQ ID NO 276 Cr - 22 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCGAGGCCCATGGTCGCCAACATGGAAATGTTCTCCATGGTGTTGGCTCCCGTAT<SEQ ID NO 277 Cr - 23 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGTACGAATTATACTACAGAGGGCGTCCGCGTTGGGGAGAGCAGGTGTGACGGAT<SEQ ID NO 278 Cr - 23 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCCCCAACGCGGACGCCCTCTGTAGTATAATTCGTACTGGTGTTGGCTCCCGTAT<SEQ ID NO 279 Cr - 24 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACGCAACCTACCTCTCACGGCTGTTCATGACGGACTTAGAGCAGGTGTGACGGAT<SEQ ID NO 280 Cr - 24 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTAAGTCCGTCATGAACAGCCGTGAGAGGTAGGTTGCGTGGTGTTGGCTCCCGTAT<SEQ ID NO 281 Cr - 25 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATGCCAGGCAAGTCATTGTGAGTATAGAATCACCTTTAGAGCAGGTGTGACGGAT<SEQ ID NO 282 Cr - 25 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTAAAGGTGATTCTATACTCACAATGACTTGCCTGGCATGGTGTTGGCTCCCGTAT<SEQ ID NO 283 Cr - 26 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGGACCGTCGATGATTGCAGGTGCGTGGTAAATACGCAGAGCAGGTGTGACGGAT<SEQ ID NO 284 Cr - 26 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGCGTATTTACCACGCACCTGCAATCATCGACGGTCCTGGTGTTGGCTCCCGTAT<SEQ ID NO 285 Cr - 27 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATGCTACATCGGTCAGAAGATCCGAGCCTGCCCGCGTAGAGCAGGTGTGACGGAT<SEQ ID NO 286 Cr - 27 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTACGCGGGCAGGCTCGGATCTTCTGACCGATGTAGCATGGTGTTGGCTCCCGTAT<SEQ ID NO 287 Cr - 28 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAACTGGGAAACGTTGATCGTAGCTGAGTGATAGTGCTAGAGCAGGTGTGACGGAT<SEQ ID NO 288 Cr - 28 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTAGCACTATCACTCAGCTACGATCAACGTTTCCCAGTTGGTGTTGGCTCCCGTAT<SEQ ID NO 289 Cr - 28.1 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAATGTTTGAAGCAAAGCCGAGGCATGTAGAAACGTCTAGAGCAGGTGTGACGGAT<SEQ ID NO 290 Cr - 28.1 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTAGACGTTTCTACATGCCTCGGCTTTGCTTCAAACATTGGTGTTGGCTCCCGTAT<SEQ ID NO 291 Cr - 29 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGAGGGGGTCAAAAATGCTAGAGAATACACCGTCAGCAGAGCAGGTGTGACGGAT<SEQ ID NO 292 Cr - 29 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGCTGACGGTGTATTCTCTAGCATTTTTGACCCCCTCTGGTGTTGGCTCCCGTAT<SEQ ID NO 293 Cr - 30 F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAAAGCGAGCTCGGCATGTCGACGGTGTGCGTCCACCGAGAGCAGGTGTGACGGAT<SEQ ID NO 294 Cr - 30 R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCGGTGGACGCACACCGTCGACATGCCGAGCTCGCTTTGGTGTTGGCTCCCGTAT<SEQ ID NO 295 G 1/4F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATTCCCCCCTCTCGTTCTGTTGCCCCGTATCCTAATTAGAGCAGGTGTGACGGAT<SEQ ID NO 296 G 2F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGCCGGATATCCGATGTGCTTGTCTGACCTGGTCCGAGAGCAGGTGTGACGGAT<SEQ ID NO 297 G 5F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACTGTTATGTTAGCTCCTCCCTAAACTCTTTGACTCAAGAGCAGGTGTGACGGAT<SEQ ID NO 298 G 7F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACCGCATGCGTTCCCAGCCCGCTGATGCATTGTTGTTAGAGCAGGTGTGACGGAT<SEQ ID NO 299 G 8F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGATCCTGAAACTATCACTCCTGCTTATAACCTGTTCAGAGCAGGTGTGACGGAT<SEQ ID NO 300 G 9F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAACCCGGGTGCTGACCACTCGGTTTGCGAGCCGCCGAGAGCAGGTGTGACGGAT<SEQ ID NO 301 G 10F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACTATGTTTTCACGGTCTTGTGGATTACGTCTTGCGCAGAGCAGGTGTGACGGAT<SEQ ID NO 302 G 21F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGAGCAGGTGTGATGGATATACGGGAGCCAACACCAGAGCAGGTGTGACGGAT<SEQ ID NO 303 G 22F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGAGCAGGTGTGATGGATATACGGGAGCCAACACCAGAGCAGGTGTGACGGAT<SEQ ID NO 304 G 23F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGAGCAGGTGTGATGGATATACGGGAGCCAACACCAGAGCAGGTGTGACGGAT<SEQ ID NO 305 G 24F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGCACCTGAAGATCAAGTGTGAGTTATAGGTTGCGTTTGGTGTTGGCTCCCGTAT<SEQ ID NO 306 G 29F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAATGCACTCGTCACGCCTTTTTTGCTCTTGCGCGTTAAGAGCAGGTGTGACGGAT<SEQ ID NO 307 G 34F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAACTGGTCTCTACGGAAACCTTACGCCAATCTACACAGAGCAGGTGTGACGGAT<SEQ ID NO 308 G 38F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATTAGCAACGATTCCCCTGTTAGTTCCGGTGCATCCCAGAGCAGGTGTGACGGAT<SEQ ID NO 309 G 39F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGAGCAGGTGTGAGGTCGAATTCCAGCACACTGGCGGCCGTTACTAGTGGAT<SEQ ID NO 310 G 1/4R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTAATTAGGATACGGGGCAACAGAACGAGAGGGGGGAATGGTGTTGGCTCCCGTAT<SEQ ID NO 311 G 2R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCGGACCAGGTCAGACAAGCACATCGGATATCCGGCTGGTGTTGGCTCCCGTAT<SEQ ID NO 312 G 5R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTGAGTCAAAGAGTTTAGGGAGGAGCTAACATAACAGTGGTGTTGGCTCCCGTAT<SEQ ID NO 313 G 7R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTAACAACAATGCATCAGCGGGCTGGGAACGCATGCGGTGGTGTTGGCTCCCGTAT<SEQ ID NO 314 G 8R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGAACAGGTTATAAGCAGGAGTGATAGTTTCAGGATCTGGTGTTGGCTCCCGTAT<SEQ ID NO 315 G 9R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCGGCGGCTCGCAAACCGAGTGGTCAGCACCCGGGTTGGTGTTGGCTCCCGTAT<SEQ ID NO 316 G 10R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGCGCAAGACGTAATCCACAAGACCGTGAAAACATAGTGGTGTTGGCTCCCGTAT<SEQ ID NO 317 G 21R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGGTGTTGGCTCCCGTATATCCATCACACCTGCTCTGGTGTTGGCTCCCGTAT<SEQ ID NO 318 G 22R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGGTGTTGGCTCCCGTATATCCATCACACCTGCTCTGGTGTTGGCTCCCGTAT<SEQ ID NO 319 G 23R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGGTGTTGGCTCCCGTATATCCATCACACCTGCTCTGGTGTTGGCTCCCGTAT<SEQ ID NO 320 G 24R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGCACCTGAAGATCAAGTGTGAGTTATAGGTTGCGTTTGGTGTTGGCTCCCGTAT<SEQ ID NO 321 G 29R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTAACGCGCAAGAGCAAAAAAGGCGTGACGAGTGCATTGGTGTTGGCTCCCGTAT<SEQ ID NO 322 G 34R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGTGTAGATTGGCGTAAGGTTTCCGTAGAGACCAGTTGGTGTTGGCTCCCGTAT<SEQ ID NO 323 G 38R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGGGATGCACCGGAACTAACAGGGGAATCGTTGCTAATGGTGTTGGCTCCCGTAT<SEQ ID NO 324 G 39R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCACTAGTAACGGCCGCCAGTGTGCTGGAATTCGACCTCACACCTGCTCTGGTGTTGGCTCCCGTAT<SEQ ID NO 325 H33F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGGGGGATGGCCGCTTGACATTGACACGTACCTGTGGAGAGCAGGTGTGACGGAT<SEQ ID NO 326 H33R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCCACAGGTACGTGTCAATGTCAAGCGGCCATCCCCCTGGTGTTGGCTCCCGTAT<SEQ ID NO 327 H37F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACAAGAGGCCGTACGAAAAAATAACTATGCAATTGTAGAGCAGGTGTGACGGAT<SEQ ID NO 328 H37R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTACAATTGCATAGTTATTTTTTCGTACGGCCTCTTGTGGTGTTGGCTCCCGTAT<SEQ ID NO 329 H39F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAAACCAAGGAAGAATAAAACGATCGAGTGATCACACCAGAGCAGGTGTGACGGAT <SEQ ID NO 330 H39R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGGTGTGATCACTCGATCGTTTTATTCTTCCTTGGTTTGGTGTTGGCTCCCGTAT<SEQ ID NO 331 H41F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACAAGCGGAGCTAGCTGGGTCCGTGGATCCAAGCATGAGAGCAGGTGTGACGGAT<SEQ ID NO 332 H41R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCATGCTTGGATCCACGGACCCAGCTAGCTCCGCTTGTGGTGTTGGCTCCCGTAT<SEQ ID NO 333 H42F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATGGCACGCAGAAAACGTTAAAGCAGAATTTCCTCAGAGAGCAGGTGTGACGGAT<SEQ ID NO 334 H42R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCTGAGGAAATTCTGCTTTAACGTTTTCTGCGTGCCATGGTGTTGGCTCCCGTAT<SEQ ID NO 335 H43F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGACTTATTCTCGCAGATCCATAAAAGGATACACCCCAGAGCAGGTGTGACGGAT<SEQ ID NO 336 H43R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGGGGTGTATCCTTTTATGGATCTGCGAGAATAAGTCTGGTGTTGGCTCCCGTAT<SEQ ID NO 337 H49F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACAGAATCACGTGGAGTACGAACAATTGATTCACCCAAGAGCAGGTGTGACGGAT<SEQ ID NO 338 H49R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTGGGTGAATCAATTGTTCGTACTCCACGTGATTCTGTGGTGTTGGCTCCCGTAT<SEQ ID NO 339 H52F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACGGGGGCATCTTCCATTAACCCATTACCTCACCCCAAGAGCAGGTGTGACGGAT<SEQ ID NO 340 H52R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTGGGGTGAGGTAATGGGTTAATGGAAGATGCCCCCGTGGTGTTGGCTCCCGTAT<SEQ ID NO 341 H54F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGAAAAAAACAAACCCAAGGAATTACACCACAAAAGTAGAGCAGGTGTGACGGAT<SEQ ID NO 342 H54R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTACTTTTGTGGTGTAATTCCTTGGGTTTGTTTTTTTCTGGTGTTGGCTCCCGTAT<SEQ ID NO 343 H55F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATAAGCAGAGAACTACAAGACGATCCCATATTCCAAAGAGCAGGTGTGACGGAT<SEQ ID NO 344 H55R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTTGGAATATGGGATCGTCTTGTAGTTCTCTGCTTATGGTGTTGGCTCCCGTAT<SEQ ID NO 345 H56F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGGTTGGCGTCAAAAGAAATAAGGGATATACATTAGAGAGCAGGTGTGACGGAT<SEQ ID NO 346 H56R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCTAATGTATATCCCTTATTTCTTTTGACGCCAACCTGGTGTTGGCTCCCGTAT<SEQ ID NO 347 H57F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACGGGGTCCCCATCGTGGCCGACATAACAAAAATCCTAGAGCAGGTGTGACGGAT<SEQ ID NO 348 H57R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTAGGATTTTTGTTATGTCGGCCACGATGGGGACCCCGTGGTGTTGGCTCCCGTAT<SEQ ID NO 349 H58F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATGAGGCTCACAGTAAGAGAAGGACCTTGGACTCGTCAGAGCAGGTGTGACGGAT<SEQ ID NO 350 H58R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGACGAGTCCAAGGTCCTTCTCTTACTGTGAGCCTCATGGTGTTGGCTCCCGTAT<SEQ ID NO 351 H 60F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGCACGCCCTACTTTACCGCCGAGAATATGAGAATAGAGAGCAGGTGTGACGGAT<SEQ ID NO 352 H60R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCTATTCTCATATTCTCGGCGGTAAAGTAGGGCGTGCTGGTGTTGGCTCCCGTAT<SEQ ID NO 353 RH31F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACCGATGCGGGCGCCTTCGGCGGACCGCGAGGCCTCGAGAGCAGGTGTGACGGAT<SEQ ID NO 354 RH31R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCGAGGCCTCGCGGTCCGCCGAAGGCGCCCGCATCGGTGGTGTTGGCTCCCGTAT<SEQ ID NO 355 RH34F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGGCGTAACGTATTGAGCAGAATAAATAAGACACGATAGAGCAGGTGTGACGGAT<SEQ ID NO 356 RH34R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTATCGTGTCTTATTTATTCTGCTCAATACGTTACGCCTGGTGTTGGCTCCCGTAT<SEQ ID NO 357 RH35AF; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGGCGGACGCCGACCGGGCGGGCCCGGTCGAGGTTTTAGAGCAGGTGTGACGGAT<SEQ ID NO 358 RH35AR; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTAAAACCTCGACCGGGCCCGCCCGGTCGGCGTCCGCCTGGTGTTGGCTCCCGTAT<SEQ ID NO 359 RH35BF; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGGCGGGCTCGCGCGTCTCCCAGAGCCGAGTCATATGAGAGCAGGTGTGACGGAT<SEQ ID NO 360 RH35BR; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCATATGACTCGGCTCTGGGAGACGCGCGAGCCCGCCTGGTGTTGGCTCCCGTAT<SEQ ID NO 361 RH36AF; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACGTACCAATCCCCTCGGATTAACTCGAACAACGGTAAGAGCAGGTGTGACGGAT<SEQ ID NO 362 RH36AR; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTACCGTTGTTCGAGTTAATCCGAGGGGATTGGTACGTGGTGTTGGCTCCCGTAT<SEQ ID NO 363 RH36BF; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACTGGTGAGGCGCCTGCGCCGACTGGCCGTCCCCCCGAGAGCAGGTGTGACGGAT<SEQ ID NO 364 RH36BR; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCGGGGGGACGGCCAGTCGGCGCAGGCGCCTCACCAGTGGTGTTGGCTCCCGTAT<SEQ ID NO 365 RH37F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGCAGGGTGGCGCGACCGACCTATTTGTTGGCTATTAGAGCAGGTGTGACGGAT<SEQ ID NO 366 RH37R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTAATAGCCAACAAATAGGTCGGTCGCGCCACCCTGCTGGTGTTGGCTCCCGTAT<SEQ ID NO 367 RH38F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACTAACAAGAAGAACGACACGTACAGCAGTACTTACCAGAGCAGGTGTGACGGAT<SEQ ID NO 368 RH38R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGGTAAGTACTGCTGTACGTGTCGTTCTTCTTGTTAGTGGTGTTGGCTCCCGTAT<SEQ ID NO 369 RH39F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACCACGCTAGCGCACCAAAATCTATAAACCGAATCCTAGAGCAGGTGTGACGGAT<SEQ ID NO 370 RH39R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTAGGATTCGGTTTATAGATTTTGGTGCGCTAGCGTGGTGGTGTTGGCTCCCGTAT<SEQ ID NO 371 RH42F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGAGCAGGTGTGACGGATAGAGCAGGTAGAGCAGGTGTGACGGAT <SEQ IDNO 372 RH42R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTACCTGCTCTATCCGTCACACCTGCTCTGGTGTTGGCTCCCGTAT <SEQ IDNO 373 RH45/60F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACGAACCCCCGGTCCCCCGGGGGACTATATTCCTACGAGAGCAGGTGTGACGGAT<SEQ ID NO 374 RH45/60R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCGTAGGAATATAGTCCCCCGGGGGACCGGGGGTTCGTGGTGTTGGCTCCCGTAT<SEQ ID NO 375 RH49F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAACGGAGAGCTTCTCCGCATGTGAACCGTTACCTTCCAGAGCAGGTGTGACGGAT<SEQ ID NO 376 RH49R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGGAAGGTAACGGTTCACATGCGGAGAAGCTCTCCGTTGGTGTTGGCTCCCGTAT<SEQ ID NO 377 RH50F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACATGACGGGTGACTAAAAGACGAAATCTCCCAATTAAGAGCAGGTGTGACGGAT<SEQ ID NO 378 RH50R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTAATTGGGAGATTTCGTCTTTTAGTCACCCGTCATGTGGTGTTGGCTCCCGTAT<SEQ ID NO 379 RH54F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACCTGAGCGCCGGCAGCACTCACTATTTGTCCCCGCAAGAGCAGGTGTGACGGAT<SEQ ID NO 380 RH54R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTGCGGGGACAAATAGTGAGTGCTGCCGGCGCTCAGGTGGTGTTGGCTCCCGTAT<SEQ ID NO 381 RH55F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAACATCCTCTGCTGCCGGCCGGATTCGGCCGAGTGCCAGAGCAGGTGTGACGGAT<SEQ ID NO 382 RH55R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGGCACTCGGCCGAATCCGGCCGGCAGCAGAGGATGTTGGTGTTGGCTCCCGTAT<SEQ ID NO 383 RH57F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACGCCGCCCCAGCGTCATCGGAAGTCTAATCAGATCCAGAGCAGGTGTGACGGAT<SEQ ID NO 384 RH57R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGGATCTGATTAGACTTCCGATGACGCTGGGGCGGCGTGGTGTTGGCTCCCGTAT<SEQ ID NO 385 RH58F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGGGTGGCGCCGGCCAGCGACTCCTGCCTTCCAAGCTAGAGCAGGTGTGACGGAT<SEQ ID NO 386 RH58R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTAGCTTGGAAGGCAGGAGTCGCTGGCCGGCGCCACCCTGGTGTTGGCTCCCGTAT<SEQ ID NO 387 AR31F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGACGGGTTGGATCACGCCTAATTGGGCCCATGTTTTAGAGCAGGTGTGACGGAT<SEQ ID NO 388 AR31R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTAAAACATGGGCCCAATTAGGCGTGATCCAACCCGTCTGGTGTTGGCTCCCGTAT<SEQ ID NO 389 AR32F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACTCTCAAGTCGAAGATAGACGAAAAGATTTCGCCCCAGAGCAGGTGTGACGGAT<SEQ ID NO 390 AR32R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGGGGCGAAATCTTTTCGTCTATCTTCGACTTGAGAGTGGTGTTGGCTCCCGTAT<SEQ ID NO 391 AR33F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATGCGAGCATCATTACTTCCTACCATGGATCCGGACTAGAGCAGGTGTGACGGAT<SEQ ID NO 392 AR33R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTAGTCCGGATCCATGGTAGGAAGTAATGATGCTCGCATGGTGTTGGCTCCCGTAT<SEQ ID NO 393 AR34F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATCGGCGACCGTTAGCCTTCCGGCTACAATCAGGGCCAGAGCAGGTGTGACGGAT<SEQ ID NO 394 AR34R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGGCCCTGATTGTAGCCGGAAGGCTAACGGTCGCCGATGGTGTTGGCTCCCGTAT<SEQ ID NO 395 AR35F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGAGCGGGTGTGACGGATATACGGGAGCCAACACCAGAGCAGGTGTGACGGAT<SEQ ID NO 396 AR35R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGGTGTTGGCTCCCGTATATCCGTCACACCCGCTCTGGTGTTGGCTCCCGTAT<SEQ ID NO 397 AR36F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACCGAATTGATTGATAAAAAGGGTTAGATCGCTCCAGAGCAGGTGTGACGGAT<SEQ ID NO 398 AR36R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGGAGCGATCTAACCCTTTTTATCAATCAATTCGGTGGTGTTGGCTCCCGTAT<SEQ ID NO 399 AR38F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGCAGGGAGCAATAAAAACCATTAAAAGTCAGCTGACAGAGCAGGTGTGACGGAT<SEQ ID NO 400 AR38R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGTCAGCTGACTTTTAATGGTTTTTATTGCTCCCTGCTGGTGTTGGCTCCCGTAT<SEQ ID NO 401 AR39/57F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACAGGCTCACGACCCCGGCTTGGGCCGGGCCCTCCCCAGAGCAGGTGTGACGGAT<SEQ ID NO 402 AR39/57R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGGGGAGGGCCCGGCCCAAGCCGGGGTCGTGAGCCTGTGGTGTTGGCTCCCGTAT<SEQ ID NO 403 AR41F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATCCCAAGTCAATACCTCCGAAATAAGTTGAATTACCAGAGCAGGTGTGACGGAT<SEQ ID NO 404 AR41R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGGTAATTCAACTTATTTCGGAGGTATTGACTTGGGATGGTGTTGGCTCCCGTAT<SEQ ID NO 405 AR42F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGTATCTGGATCAAGAGAACTGAAGGATATTTCTAACAGAGCAGGTGTGACGGAT<SEQ ID NO 406 AR42R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGTTAGAAATATCCTTCAGTTCTCTTGATCCAGATACTGGTGTTGGCTCCCGTAT<SEQ ID NO 407 AR45F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACGTGCTGACTATACTATTCAAAAACAACACCCTAGGAGAGCAGGTGTGACGGAT<SEQ ID NO 408 AR45R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCCTAGGGTGTTGTTTTTGAATAGTATAGTCAGCACGTGGTGTTGGCTCCCGTAT<SEQ ID NO 409 AR47F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACGGATAAGAATCAATAGGCAATGAAAGAAGACCGGCAGAGCAGGTGTGACGGAT<SEQ ID NO 410 AR47R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGCCGGTCTTCTTTCATTGCCTATTGATTCTTATCCGTGGTGTTGGCTCCCGTAT<SEQ ID NO 411 AR48F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACGCGAAGCGAGATCCGCCGTATTAGCAATTTGTGTGAGAGCAGGTGTGACGGAT<SEQ ID NO 412 AR48R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCACACAAATTGCTAATACGGCGGATCTCGCTTCGCGTGGTGTTGGCTCCCGTAT<SEQ ID NO 413 AR49F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACCGACCATGGAGCGGACCCATTAGATCTTCAATCCTAGAGCAGGTGTGACGGAT<SEQ ID NO 414 AR49R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTAGGATTGAAGATCTAATGGGTCCGCTCCATGGTCGGTGGTGTTGGCTCCCGTAT<SEQ ID NO 415 AR51F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACCCCGACCAGGAGCCGGGGCTCCCGCCCGCCTCCCCAGAGCAGGTGTGACGGAT<SEQ ID NO 416 AR51R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGGGGAGGCGGGCGGGAGCCCCGGCTCCTGGTCGGGGTGGTGTTGGCTCCCGTAT<SEQ ID NO 417 AR54F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGGCGAGCGGTCCACGGCCGGCCGGACCGTCAATGGTAGAGCAGGTGTGACGGAT<SEQ ID NO 418 AR54R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTACCATTGACGGTCCGGCCGGCCGTGGACCGCTCGCCTGGTGTTGGCTCCCGTAT<SEQ ID NO 419 AR55F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGGAGGCGGACGATCTCCCTCCCGGCCAAAGGCGCGTAGAGCAGGTGTGACGGAT<SEQ ID NO 420 AR55R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTACGCGCCTTTGGCCGGGAGGGAGATCGTCCGCCTCCTGGTGTTGGCTCCCGTAT<SEQ ID NO 421 AR56F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACGGATAAGAATCAATAGGCAATGAAAGAAGACCGGCAGAGCAGGTGTGACGGAT<SEQ ID NO 422 AR56R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGCCGGTCTTCTTTCATTGCCTATTGATTCTTATCCGTGGTGTTGGCTCCCGTAT<SEQ ID NO 423 AR58F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACTGTTTAATAAATGCACCTGAAAAAAACGTGTGTCAAGAGCAGGTGTGACGGAT<SEQ ID NO 424 AR58R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTGACACACGTTTTTTTCAGGTGCATTTATTAAACAGTGGTGTTGGCTCCCGTAT<SEQ ID NO 425 AR59F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAAGCGTCTAGCGGGACTAAGCTGAAACATACCAGCTAGAGCAGGTGTGACGGAT<SEQ ID NO 426 AR59R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTAGCTGGTATGTTTCAGCTTAGTCCCGCTAGACGCTTGGTGTTGGCTCCCGTAT<SEQ ID NO 427 AR60F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGGCGACCGACACGATTATAACCTTGTAAAGGCCGTAAGAGCAGGTGTGACGGAT<SEQ ID NO 428 AR60R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTACGGCCTTTACAAGGTTATAATCGTGTCGGTCGCCTGGTGTTGGCTCCCGTAT<SEQ ID NO 429 VD3 10F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGTACGGCGGTGTCCGAACTCACTATACCCAGTTGAAAGAGCAGGTGTGACGGAT<SEQ ID NO 430 VD3 10R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTTCAACTGGGTATAGTGAGTTCGGACACCGCCGTACTGGTGTTGGCTCCCGTAT<SEQ ID NO 431 VD3 13F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGACCTGACAACGAAAACCCCAGTTGTCGCCATAGCCAGAGCAGGTGTGACGGAT <SEQ ID NO 432 VD3 13R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGGCTATGGCGACAACTGGGGTTTTCGTTGTCAGGTCTGGTGTTGGCTCCCGTAT<SEQ ID NO 433 VD3 14F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATAGTGTTGGGCCAATACGGTAACGTGTCCTTGGAGAGCAGGTGTGACGGAT<SEQ ID NO 434 VD3 14R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCCAAGGACACGTTACCGTATTGGCCCAACACTATGGTGTTGGCTCCCGTAT<SEQ ID NO 435 VD3 15F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATAAGCGCAACACAGTCCATCCCTGAGTGAGATAGCGAGAGCAGGTGTGACGGAT<SEQ ID NO 436 VD3 15R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCGCTATCTCACTCAGGGATGGACTGTGTTGCGCTTATGGTGTTGGCTCCCGTAT<SEQ ID NO 437 VD3 16F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACGCACATACTAGCTATCTCATCAGAGCAGGTGTGACGGAT <SEQ ID NO438 VD3 16R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGATGAGATAGCTAGTATGTGCGTGGTGTTGGCTCCCGTAT <SEQ ID NO439 VD3 17F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACTAACTTGTTGCTGATCTTACCAGAGCAGGTGTGACGGAT <SEQ ID NO440 VD3 17R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGGTAAGATCAGCAACAAGTTAGTGGTGTTGGCTCCCGTAT <SEQ ID NO441 VD3 18F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACCCGTTTTTGATCTAATGAGGATACAATATTCGTCNAGAGCAGGTGTGACGGAT<SEQ ID NO 442 VD3 18R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTNGACGAATATTGTATCCTCATTAGATCAAAAACGGGTGGTGTTGGCTCCCGTAT<SEQ ID NO 443 VD3 19F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGTTGTGGGAACATCAGGCTAAGTATGAGACGGAACGAGAGCAGGTGTGACGGAT<SEQ ID NO 444 VD3 19R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCGTTCCGTCTCATACTTAGCCTGATGTTCCCACAACTGGTGTTGGCTCCCGTAT<SEQ ID NO 445 VD3 1F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATAGACAATGGCGTACTTTTCGTAATTCCACAAGAATAGAGCAGGTGTGACGGAT<SEQ ID NO 446 VD3 1R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTATTCTTGTGGAATTACGAAAAGTACGCCATTGTCTATGGTGTTGGCTCCCGTAT<SEQ ID NO 447 VD3 20F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATAGTGTTGGGCCAATACGGTAACGTGTCCTTGGAGAGCAGGTGTGACGGAT<SEQ ID NO 448 VD3 20R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCCAAGGACACGTTACCGTATTGGCCCAACACTATGGTGTTGGCT CCCGTAT<SEQ ID NO 449 VD3 2F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACCACAAAAGCATTCGCCCTTACAGAGCAGGTGTGACGGAT <SEQ ID NO450 VD3 2R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGTAAGGGCGAATGCTTTTGTGGTGGTGTTGGCTCCCGTAT <SEQ ID NO451 VD3 3F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGCGTGTAGCTAGTTTCAGGATTGTAGTATGTAATATAGAGCAGGTGTGACGGAT<SEQ ID NO 452 VD3 3R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTATATTACATACTACAATCCTGAAACTAGCTACACGCTGGTGTTGGCTCCCGTAT<SEQ ID NO 453 VD3 5F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACGCACATACTAGCTATCTCATCAGAGCAGGTGTGACGGAT <SEQ ID NO454 VD3 5R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGATGAGATAGCTAGTATGTGCGTGGTGTTGGCTCCCGTAT <SEQ ID NO455 VD3 6F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATCAGAGATCATCTAACGAAAATCATGGGTCTCGCCCAGAGCAGGTGTGACGGAT<SEQ ID NO 456 VD3 6R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGGGCGAGACCCATGATTTTCGTTAGATGATCTCTGATGGTGTTGGCTCCCGTAT<SEQ ID NO 457 VD3 7F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGCAAAGAATAGTGAGCCCTATGATCATCTGTTCGTCAGAGCAGGTGTGACGGAT<SEQ ID NO 458 VD3 7R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGACGAACAGATGATCATAGGGCTCACTATTCTTTGCTGGTGTTGGCTCCCGTAT<SEQ ID NO 459 VD3 8F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGACATCATGTCGCATATCTGGATCTAGAGGCTATTCAGAGCAGGTGTGACGGAT<SEQ ID NO 460 VD3 8R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGAATAGCCTCTAGATCCAGATATGCGACATGATGTCTGGTGTTGGCTCCCGTAT<SEQ ID NO 461 VD3 22/47/52/53F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATAGTGTTGGGCCAATACGGTAACGTGTACTTGGAGAGCAGGTGTGACGGAT<SEQ ID NO 462 VD3 22/47/52/53R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCCAAGTACACGTTACCGTATTGGCCCAACACTATGGTGTTGGCTCCCGTAT<SEQ ID NO 463 VD3 23F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGAGAGTTCATGTTGCACCCGGGTCGTCGCGTTATGCAGAGCAGGTGTGACGGAT<SEQ ID NO 463 VD3 23R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGCATAACGCGACGACCCGGGTGCAACATGAACTCTCTGGTGTTGGCTCCCGTAT<SEQ ID NO 465 VD3 24F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATCTATCTGAGGCCTATTTAGCACCTGTTGTCACCCTAGAGCAGGTGTGACGGAT<SEQ ID NO 466 VD3 24R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTAGGGTGACAACAGGTGCTAAATAGGCCTCAGATAGATGGTGTTGGCTCCCGTAT<SEQ ID NO 467 VD3 27F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATTCTATCGTTCCGGACGCTTATGCCTTGCCATCTACAGAGCAGGTGTGACGGAT<SEQ ID NO 468 VD3 27R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGTAGATGGCAAGGCATAAGCGTCCGGAACGATAGAATGGTGTTGGCTCCCGTAT<SEQ ID NO 469 VD3 28F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACATTTCGCACACCCGAGCCCTAGAGGGCTAGGGACCAGAGCAGGTGTGACGGAT <SEQ ID NO 470 VD3 28R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGGTCCCTAGCCCTCTAGGGCTCGGGTGTGCGAAATGTGGTGTTGGCTCCCGTAT<SEQ ID NO 471 VD3 29F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACTGGCACGAACAATCATGAAATAGGGCATCCGAGAGAGAGCAGGTGTGACGGAT<SEQ ID NO 472 VD3 29R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCTCTCGGATGCCCTATTTCATGATTGTTCGTGCCAGTGGTGTTGGCTCCCGTAT<SEQ ID NO 473 VD3 30F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATGTGTCATGGTGGGCGTGGCTATCCGAGCAAGCTCTAGAGCAGGTGTGACGGAT<SEQ ID NO 474 VD3 30R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTAGAGCTTGCTCGGATAGCCACGCCCACCATGACACATGGTGTTGGCTCCCGTAT<SEQ ID NO 475 VD3 31/33F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACATGCAAATACACATCATGATGACGGATCCTATTGTAGAGCAGGTGTGACGGAT<SEQ ID NO 476 VD3 31/33R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTACAATAGGATCCGTCATCATGATGTGTATTTGCATGTGGTGTTGGCTCCCGTAT<SEQ ID NO 477 VD3 32F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGTAGAGCAAGCTATTACGCGAAGCTAGAATGAGATCAGAGCAGGTGTGACGGAT<SEQ ID NO 478 VD3 32R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGATCTCATTCTAGCTTCGCGTAATAGCTTGCTCTACTGGTGTTGGCTCCCGTAT<SEQ ID NO 479 VD3 34F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACCCATTGGGGATGCATTAGATGCAGTTGATTATGCGAGAGCAGGTGTGACGGAT<SEQ ID NO 480 VD3 34R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCGCATAATCAACTGCATCTAATGCATCCCCAATGGGTGGTGTTGGCTCCCGTAT<SEQ ID NO 481 VD3 35F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATACAACCGTCCAAGCGTTACTCTTTACATACTCTCCAGAGCAGGTGTGACGGAT<SEQ ID NO 482 VD3 35R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGGAGAGTATGTAAAGAGTAACGCTTGGACGGTTGTATGGTGTTGGCTCCCGTAT<SEQ ID NO 483 VD3 37F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAATTTTGACTGTTCCAGGCTCAGTATTGGTATTCAGGAGAGCAGGTGTGACGGAT<SEQ ID NO 484 VD3 37R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCCTGAATACCAATACTGAGCCTGGAACAGTCAAAATTGGTGTTGGCTCCCGTAT<SEQ ID NO 485 VD3 38F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACGAAATGATGTATCTAGTTCCTCGTGTCCTGATTCGAGAGCAGGTGTGACGGAT<SEQ ID NO 486 VD3 38R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCGAATCAGGACACGAGGAACTAGATACATCATTTCGTGGTGTTGGCTCCCGTAT<SEQ ID NO 487 VD3 39F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACCGCTGCCCAGGTATAACACCGCGGTACGATCTCATAGAGCAGGTGTGACGGAT<SEQ ID NO 488 VD3 39R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTATGAGATCGTACCGCGGTGTTATACCTGGGCAGCGGTGGTGTTGGCTCCCGTAT<SEQ ID NO 489 VD3 40F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAAAGGGATCTGGAAAACCCCGTATTGATCTAAGGCGCAGAGCAGGTGTGACGGAT<SEQ ID NO 490 VD3 40R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGCGCCTTAGATCAATACGGGGTTTTCCAGATCCCTTTGGTGTTGGCTCCCGTAT<SEQ ID NO 491 VD3 43F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATACCCCCCTCTTTAGGCCATCACGTTCTGTCGATTTAGAGCAGGTGTGACGGAT<SEQ ID NO 492 VD3 43R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTAAATCGACAGAACGTGATGGCCTAAAGAGGGGGGTATGGTGTTGGCTCCCGTAT<SEQ ID NO 493 VD3 45F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATACCCCCCTCTTTAGGCCATCACGTTCTCTCGATTTAGAGCAGGTGTGACGGAT<SEQ ID NO 494 VD3 45R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTAAATCGAGAGAACGTGATGGCCTAAAGAGGGGGGTATGGTGTTGGCTCCCGTAT<SEQ ID NO 495 VD3 46F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATCATGGTCGCGAATCAACCGTATCTCAGCTGCCTTGAGAGCAGGTGTGACGGAT<SEQ ID NO 496 VD3 46R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCAAGGCAGCTGAGATACGGTTGATTCGCGACCATGATGGTGTTGGCTCCCGTAT<SEQ ID NO 497 VD3 48F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACCCGTTTTTGATCTAATGAGGATACAATATTCGTCTAGAGCAGGTGTGACGGAT<SEQ ID NO 498 VD3 48R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTAGACGAATATTGTATCCTCATTAGATCAAAAACGGGTGGTGTTGGCTCCCGTAT <SEQ ID NO 499 VD3 49/55F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATATAAAAGGCGAACGGTCACTTTGGTCGGAGTACGTAGAGCAGGTGTGACGGAT<SEQ ID NO 500 VD3 49/55R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTACGTACTCCGACCAAAGTGACCGTTCGCCTTTTATATGGTGTTGGCTCCCGTAT<SEQ ID NO 501 VD3 50F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGTGTTGGCGTCTTCCCTGATCAGAGCAGGTGTGACGGAT <SEQ ID NO 502VD3 50R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGATCAGGGAAGACGCCAACACTGGTGTTGGCTCCCGTAT <SEQ ID NO 503VD3 51F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGAGGTGAGAAGCCCATTACACCGAGCGGACCTGCAGAGAGCAGGTGTGACGGAT<SEQ ID NO 504 VD3 51R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCTGCAGGTCCGCTCGGTGTAATGGGCTTCTCACCTCTGGTGTTGGCTCCCGTAT<SEQ ID NO 505 VD3 54F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGACGAAATCAAATCTAAAAGTGATAAGCCAGAAGTCAGAGCAGGTGTGACGGAT<SEQ ID NO 506 VD3 54R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGACTTCTGGCTTATCACTTTTAGATTTGATTTCGTCTGGTGTTGGCTCCCGTAT<SEQ ID NO 507 VD3 56F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACCCGTTTTTGATCTAATGAGGATACAATATTCGTCTAGAGCAGGTGTGACGGAT<SEQ ID NO 508 VD3 56R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTAGACGAATATTGTATCCTCATTAGATCAAAAACGGGTGGTGTTGGCTCCCGTAT<SEQ ID NO 509 VD3 57F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAACACGCAGAAGAGATGCATTGTATGATCGGTGTACGAGAGCAGGTGTGACGGAT<SEQ ID NO 510 VD3 57R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCGTACACCGATCATACAATGCATCTCTTCTGCGTGTTGGTGTTGGCTCCCGTAT<SEQ ID NO 511 VD3 58F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACGCCAACAGTGTTTTAGAGTCATGCACAAAAGTATCAGAGCAGGTGTGACGGAT<SEQ ID NO 512 VD3 58R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGATACTTTTGTGCATGACTCTAAAACACTGTTGGCGTGGTGTTGGCTCCCGTAT<SEQ ID NO 513 VD3 59F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGGGTGGTTTACGATCGGCAGGTCGTGCGTGCGACACAGAGCAGGTGTGACGGAT<SEQ ID NO 514 VD3 59R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGTGTCGCACGCACGACCTGCCGATCGTAAACCACCCTGGTGTTGGCTCCCGTAT<SEQ ID NO 515 VD3 60F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAACGGCGACGGGCGAGTACACAGGTGTAAGTCGGGGTAGAGCAGGTGTGACGGAT<SEQ ID NO 516 VD3 60R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTACCCCGACTTACACCTGTGTACTCGCCCGTCGCCGTTGGTGTTGGCTCCCGTAT<SEQ ID NO 517 VD3 61F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAAGCAATAGAACACCCTTTGTCGCACTGGATGCGATGAGAGCAGGTGTGACGGAT<SEQ ID NO 518 VD3 61R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCATCGCATCCAGTGCGACAAAGGGTGTTCTATTGCTTGGTGTTGGCTCCCGTAT<SEQ ID NO 519 VD3 62F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACAAAGTGTTGTAAGGGCAAAACAAATATGTACCTCGAGAGCAGGTGTGACGGAT <SEQ ID NO 520 VD3 62R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCGAGGTAGATATTTGTTTTGCCCTTACAACACTTTGTGGTGTTGGCTCCCGTAT<SEQ ID NO 521 VD3 63F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAAGCCAAAGACCCTTATCAAACGGCCATGCCCGGGGCAGAGCAGGTGTGACGGAT<SEQ ID NO 522 VD3 63R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGCCCCGGGCATGGCCGTTTGATAAGGGTCTTTGGCTTGGTGTTGGCTCCCGTAT<SEQ ID NO 523 VD3 64F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACATTAACCCCAAAGGATACATGTTTGTCCCATCGCAAGAGCAGGTGTGACGGAT<SEQ ID NO 524 VD3 64R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTGCGATGGGACAAACATGTATCCTTTGGGGTTAATGTGGTGTTGGCTCCCGTAT<SEQ ID NO 525 VD3 65F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATATCACGGACCCCCCAGGTTGCCGAATTACTCTTACAGAGCAGGTGTGACGGAT<SEQ ID NO 526 VD3 65R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGTAAGAGTAATTCGGCAACCTGGGGGGTCCGTGATATGGTGTTGGCTCCCGTAT<SEQ ID NO 527 BNP - 10F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATTCCCGCATCGCGCGTTTTCAGCCTTTGACCGTTAGAGCAGGTGTGACGGAT<SEQ ID NO 528 BNP - 10R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTAACGGTCAAAGGCTGAAAACGCGCGATGCGGGAATGGTGTTGGCTCCCGTAT<SEQ ID NO 529 BNP - 12F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAACGTGTGCTGTGTTACTGCCCTTCTCTGTAGCCGTGAGAGCAGGTGTGACGGAT<SEQ ID NO 530 BNP - 12R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCACGGCTACAGAGAAGGGCAGTAACACAGCACACGTTGGTGTTGGCTCCCGTAT<SEQ ID NO 531 BNP - 13F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACCTTTTAAAACGCTAGCCAGCTTAGTCCATTCCACCAGAGCAGGTGTGACGGAT<SEQ ID NO 532 BNP - 13R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGGTGGAATGGACTAAGCTGGCTAGCGTTTTAAAAGGTGGTGTTGGCTCCCGTAT<SEQ ID NO 533 BNP - 14aF; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAATCTAACAGATTGCAGCTCGCCTGTCCCGGCGTACTAGAGCAGGTGTGACGGAT<SEQ ID NO 534 BNP - 14aR; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTAGTACGCCGGGACAGGCGAGCTGCAATCTGTTAGATTGGTGTTGGCTCCCGTAT<SEQ ID NO 535 BNP - 14bF; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACCTATTACAGACCCAATTTCCACCTGGCATTTCTATAGAGCAGGTGTGACGGAT<SEQ ID NO 536 BNP - 14bR; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTATAGAAATGCCAGGTGGAAATTGGGTCTGTAATAGGTGGTGTTGGCTCCCGTAT<SEQ ID NO 537 BNP - 15aF; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACATATCCTACACTCCCATACCCCACTGTAGACACGCAGAGCAGGTGTGACGGAT<SEQ ID NO 538 BNP - 15aR; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGCGTGTCTACAGTGGGGTATGGGAGTGTAGGATATGTGGTGTTGGCTCCCGTAT<SEQ ID NO 539 BNP - 16F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAAACCGAGTGCTGGTGGCCCTCTCTGCCATATAAGTGAGAGCAGGTGTGACGGAT<SEQ ID NO 540 BNP - 16R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCACTTATATGGCAGAGAGGGCCACCAGCACTCGGTTTGGTGTTGGCTCCCGTAT<SEQ ID NO 541 BNP - 17F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACCTTTTAAAACGCTAGCTAGCTTAGTCCAATTCCACCAGAGCAGGTGTGACGGAT<SEQ ID NO 542 BNP - 17R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGGTGGAATTGGACTAAGCTAGCTAGCGTTTTAAAAGGTGGTGTTGGCTCCCGTAT<SEQ ID NO 543 BNP - 18F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATGACATTGCAACTATACGCTTACCCACGTCAGCTCCAGAGCAGGTGTGACGGAT<SEQ ID NO 544 BNP - 18R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGGAGCTGACGTGGGTAAGCGTATAGTTGCAATGTCATGGTGTTGGCTCCCGTAT<SEQ ID NO 545 BNP - 20F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATTAACCTGAAAGTACCAGTGTCAGTTTACCCTACCTAGAGCAGGTGTGACGGAT<SEQ ID NO 546 BNP - 20R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTAGGTAGGGTAAACTGACACTGGTACTTTCAGGTTAATGGTGTTGGCTCCCGTAT<SEQ ID NO 547 BNP - 21aF; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGGCATTAGTGTAAAGCACTAAGAGTCAGGCTGTAGCAGAGCAGGTGTGACGGAT<SEQ ID NO 548 BNP - 21aR; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGCTACAGCCTGACTCTTAGTGCTTTACACTAATGCCTGGTGTTGGCTCCCGTAT<SEQ ID NO 549 BNP - 21bF; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATGACACGCCGATTATGGACGTTGCGAACTAGTTGGTAGAGCAGGTGTGACGGAT<SEQ ID NO 550 BNP - 21bR; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTACCAACTAGTTCGCAACGTCCATAATCGGCGTGTCATGGTGTTGGCTCCCGTAT<SEQ ID NO 551 BNP - 22F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACTCAATCCCACCCTTATTTAGAGCGGTTACATCACAAGAGCAGGTGTGACGGAT<SEQ ID NO 552 BNP - 22R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTGTGATGTAACCGCTCTAAATAAGGGTGGGATTGAGTGGTGTTGGCTCCCGTAT<SEQ ID NO 553 BNP - 23aF; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAATTTGTGAAAATATTCCCGTGTTTTCCTTGAGCAGCAGAGCAGGTGTGACGGAT<SEQ ID NO 554 BNP - 23aR; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGCTGCTCAAGGAAAACACGGGAATATTTTCACAAATTGGTGTTGGCTCCCGTAT<SEQ ID NO 555 BNP - 23bF; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGCGTAAAACCTTGTACCAATTGATGACACTAGCGGTAGAGCAGGTGTGACGGAT<SEQ ID NO 556 BNP - 23bR; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTACCGCTAGTGTCATCAATTGGTACAAGGTTTTACGCTGGTGTTGGCTCCCGTAT<SEQ ID NO 557 BNP - 24F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACAGCTCACCGCGCTTGCCGTGCCTTACGTCTGTCCAAGAGCAGGTGTGACGGAT<SEQ ID NO 558 BNP - 24R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTGGACAGACGTAAGGCACGGCAAGCGCGGTGAGCTGTGGTGTTGGCTCCCGTAT<SEQ ID NO 559 BNP - 25aF; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATCACCGTACTGGAGCCATCGTTCATCCAGCAATCTAGAGCAGGTGTGACGGAT<SEQ ID NO 560 BNP - 25aR; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTAGATTGCTGGATGAACGATGGCTCCAGTACGGTGATGGTGTTGGCTCCCGTAT<SEQ ID NO 561 BNP - 25cF; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACCTCTCACATTATATTGTGAATACTTCGTGCTGTTTAGAGCAGGTGTGACGGAT<SEQ ID NO 562 BNP - 25cR; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTAAACAGCACGAAGTATTCACAATATAATGTGAGAGGTGGTGTTGGCTCCCGTAT<SEQ ID NO 563 CRP - 1F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGTGCTTCTGCCTTCCTTATGTTCTATCTGATTATCTAGAGCAGGTGTGACGGAT<SEQ ID NO 564 CRP - 1R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTAGATAATCAGATAGAACATAAGGAAGGCAGAAGCACTGGTGTTGGCTCCCGTAT<SEQ ID NO 565 CRP - 2F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAAAATTAACGTGTTGAGATATGTGGAACCTCTACTAAAGAGCAGGTGTGACGGAT<SEQ ID NO 566 CRP - 2R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTTAGTAGAGGTTCCACATATCTCAACACGTTAATTTTGGTGTTGGCTCCCGTAT<SEQ ID NO 567 CRP - 4F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGTCCCCATTCCCGTCTGAATGACTGTCCATAACAGGAGAGCAGGTGTGACGGAT<SEQ ID NO 568 CRP - 4R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCCTGTTATGGACAGTCATTCAGACGGGAATGGGGACTGGTGTTGGCTCCCGTAT<SEQ ID NO 569 CRP - 5F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACCTGAATACTAACACTAAGACCCGACTTGTGTTCACAGAGCAGGTGTGACGGAT<SEQ ID NO 570 CRP - 5R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGTGAACACAAGTCGGGTCTTAGTGTTAGTATTCAGGTGGTGTTGGCTCCCGTAT<SEQ ID NO 571 CRP - 6F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGCTAGGATGTCACCACCGGTCACTTCATGTCGAGACAGAGCAGGTGTGACGGAT<SEQ ID NO 572 CRP - 6R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGTCTCGACATGAAGTGACCGGTGGTGACATCCTAGCTGGTGTTGGCTCCCGTAT<SEQ ID NO 573 CRP - 8F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATAACTATTGGCCTCGAGCCGCTCCAGTCATCATCCTAGAGCAGGTGTGACGGAT<SEQ ID NO 574 CRP - 8R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTAGGATGATGACTGGAGCGGCTCGAGGCCAATAGTTATGGTGTTGGCTCCCGTAT<SEQ ID NO 575 CRP - 9F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGAGCTTGCTTTTCTTACGTCGTTGCCGGGAGCCGGAAGAGCAGGTGTGACGGAT<SEQ ID NO 576 CRP - 9R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTCCGGCTCCCGGCAACGACGTAAGAAAAGCAAGCTCTGGTGTTGGCTCCCGTAT<SEQ ID NO 577 CRP - 10F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACCGGGGACACTATACATTCTCTAGACAATATAGTTTAGAGCAGGTGTGACGGAT<SEQ ID NO 578 CRP - 10R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTAAACTATATTGTCTAGAGAATGTATAGTGTCCCCGGTGGTGTTGGCTCCCGTAT<SEQ ID NO 579 CRP - 11F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGATAGTTGTCCTGCATATGTTGTCGTGTGCTAATGTAGAGCAGGTGTGACGGAT<SEQ ID NO 580 CRP - 11R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTACATTAGCACACGACAACATATGCAGGACAACTATCTGGTGTTGGCTCCCGTAT<SEQ ID NO 581 CRP - 13F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAACTCTACAGCCTAATCTGCACTTTACAGGATACGTCAGAGCAGGTGTGACGGAT<SEQ ID NO 582 CRP - 13R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGACGTATCCTGTAAAGTGCAGATTAGGCTGTAGAGTTGGTGTTGGCTCCCGTAT<SEQ ID NO 583 CRP - 14F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACGCACGTGGTCTACACGGCCACCTATTCTCATTTGTAGAGCAGGTGTGACGGAT<SEQ ID NO 584 CRP - 14R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTACAAATGAGAATAGGTGGCCGTGTAGACCACGTGCGTGGTGTTGGCTCCCGTAT<SEQ ID NO 585 CRP - 16F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATCCTCTGTTCTTCACGCGGGAGCACTTTCTATCTTTAGAGCAGGTGTGACGGAT<SEQ ID NO 586 CRP - 16R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTAAAGATAGAAAGTGCTCCCGCGTGAAGAACAGAGGATGGTGTTGGCTCCCGTAT<SEQ ID NO 587 CRP - 17F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATCAATGGCAAGTTGTTCCATATTGACCATGGTTCACAGAGCAGGTGTGACGGAT<SEQ ID NO 588 CRP - 17R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGTGAACCATGGTCAATATGGAACAACTTGCCATTGATGGTGTTGGCTCCCGTAT<SEQ ID NO 589 CRP - 18F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACACTACCGTCCCACCCCCTCCCAGCTCCTCCGGCCGAGAGCAGGTGTGACGGAT<SEQ ID NO 590 CRP - 18R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCGGCCGGAGGAGCTGGGAGGGGGTGGGACGGTAGTGTGGTGTTGGCTCCCGTAT<SEQ ID NO 591 CRP - 20aF; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACTCAAGTAGTCCCATACACCACGCAAGCCTCTCTCTAGAGCAGGTGTGACGGAT<SEQ ID NO 592 CRP - 20aR; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTAGAGAGAGGCTTGCGTGGTGTATGGGACTACTTGAGTGGTGTTGGCTCCCGTAT<SEQ ID NO 593 CRP - 20bF; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAATCTTACTAGTTTGGGAAAAAAATTAAATATAAGCAAGAGCAGGTGTGACGGAT<SEQ ID NO 594 CRP - 20bR; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTGCTTATATTTAATTTTTTTCCCAAACTAGTAAGATTGGTGTTGGCTCCCGTAT<SEQ ID NO 595 CRP - 21F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACACTACCGTCCCACCCCCTCCCAGCTCCTCCGGCCGAGAGCAGGTGTGACGGAT<SEQ ID NO 596 CRP - 21R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCGGCCGGAGGAGCTGGGAGGGGGTGGGACGGTAGTGTGGTGTTGGCTCCCGTAT<SEQ ID NO 597 CRP - 22F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGCCTAGCTCGCTCCCAAAAGAGTCCACGCCCCGGATAGAGCAGGTGTGACGGAT<SEQ ID NO 598 CRP - 22R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTATCCGGGGCGTGGACTCTTTTGGGAGCGAGCTAGGCTGGTGTTGGCTCCCGTAT<SEQ ID NO 599 CRP - 23F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAACAAATTTCCAGCGCTATGGGCCCTAATTACCACTAAGAGCAGGTGTGACGGAT<SEQ ID NO 600 CRP - 23R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTAGTGGTAATTAGGGCCCATAGCGCTGGAAATTTGTTGGTGTTGGCTCCCGTAT<SEQ ID NO 601 CRP - 24F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACCTGCCTTACACCTTTACACTTCCGATAAATTGCCGAGAGCAGGTGTGACGGAT<SEQ ID NO 602 CRP - 24R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCGGCAATTTATCGGAAGTGTAAAGGTGTAAGGCAGGTGGTGTTGGCTCCCGTAT<SEQ ID NO 603 CRP - 25F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATAAAGTCAATTCCAACGCAGACCATCCTCACCCCCAAGAGCAGGTGTGACGGAT<SEQ ID NO 604 CRP - 25R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTGGGGGTGAGGATGGTCTGCGTTGGAATTGACTTTATGGTGTTGGCTCCCGTAT<SEQ ID NO 605 CRP - 26F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAAAGGACGCCCCCCTTCGTCCCGCGCTCGGTAGCAAAGAGCAGGTGTGACGGAT<SEQ ID NO 606 CRP - 26R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTTGCTACCGAGCGCGGGACGAAGGGGGGCGTCCTTTGGTGTTGGCTCCCGTAT<SEQ ID NO 607 CRP - 27F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATGTCCCTTGGGCACACACAACCAATCCCCACTCTCCAGAGCAGGTGTGACGGAT<SEQ ID NO 608 CRP - 27R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGGAGAGTGGGGATTGGTTGTGTGTGCCCAAGGGACATGGTGTTGGCTCCCGTAT<SEQ ID NO 609 CRP - 29F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACCCTGCTGGCTTCGGTCCGTTTCATGGTCTGCAAGCAGAGCAGGTGTGACGGAT<SEQ ID NO 610 CRP - 29R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGCTTGCAGACCATGAAACGGACCGAAGCCAGCAGGGTGGTGTTGGCTCCCGTAT<SEQ ID NO 611 CRP - 30F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACACTACCGTCCCACCCCCTCCCAGCTCCTCCGGCCGAGAGCAGGTGTGACGGAG<SEQ ID NO 612 CRP - 30R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCGGCCGGAGGAGCTGGGAGGGGGTGGGACGGTAGTGTGGTGTTGGCTCCCGTAT<SEQ ID NO 613 IL6 - 1F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATGCTGCGGGACCGCCATCTACCTGTTCATGTGTCTGAGAGCAGGTGTGACGGAT<SEQ ID NO 614 IL6 - 1R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCAGACACATGAACAGGTAGATGGCGGTCCCGCAGCATGGTGTTGGCTCCCGTAT<SEQ ID NO 615 IL6 - 2F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGGATGCGGCTTACATTACGCCTGTTTGTCATCTGGAGAGCAGGTGTGACGGAT<SEQ ID NO 616 IL6 - 2R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCCAGATGACAAACAGGCGTAATGTAAGCCGCATCCTGGTGTTGGCTCCCGTAT<SEQ ID NO 617 IL6 - 3F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGTGCCCTGGAGACGGACTGTCGGGGATCGTTCACTCAGAGCAGGTGTGACGGAT<SEQ ID NO 618 IL6 - 3R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGAGTGAACGATCCCCGACAGTCCGTCTCCAGGGCACTGGTGTTGGCTCCCGTAT<SEQ ID NO 619 IL6 4F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATATTCTGCCTGGAGATCTAGTCCCCTGCTCTCCCACAGAGCAGGTGTGACGGAT<SEQ ID NO 620 IL6 - 4R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGTGGGAGAGCAGGGGACTAGATCTCCAGGCAGAATATGGTGTTGGCTCCCGTAT<SEQ ID NO 621 IL6 - 6F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATCAAGGGCTTCACTCATAAATTATTAATGTGTCCCCAGAGCAGGTGTGACGGAT<SEQ ID NO 622 IL6 - 6R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGGGGACACATTAATAATTTATGAGTGAAGCCCTTGATGGTGTTGGCTCCCGTAT<SEQ ID NO 623 IL6 - 8F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACCCACTCTCCCCCCGCTCCCGCTCCTCCGCTCCGCGAGAGCAGGTGTGACGGAT<SEQ ID NO 624 IL6 - 8R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCGCGGAGCGGAGGAGCGGGAGCGGGGGGAGAGTGGGTGGTGTTGGCTCCCGTAT<SEQ ID NO 625 IL6 - 9F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATATCTATGTACTACCACAATCAAGTTCTTCCTCACTAGAGCAGGTGTGACGGAT<SEQ ID NO 626 IL6 - 9R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTAGTGAGGAAGAACTTGATTGTGGTAGTACATAGATATGGTGTTGGCTCCCGTAT<SEQ ID NO 627 IL6 - 10/11F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACCTTTTAAAACGCTAGCTAGCTTAGTCCATTCCACCAGAGCAGGTGTGACGGAT<SEQ ID NO 628 IL6 - 10/11R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGGTGGAATGGACTAAGCTAGCTAGCGTTTTAAAAGGTGGTGTTGGCTCCCGTAT<SEQ ID NO 629 IL6 - 12F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATTAGTGATCGGTGGCTCAAACTTACGCTCGCTCCGAAGAGCAGGTGTGACGGAT<SEQ ID NO 630 IL6 - 12R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTCGGAGCGAGCGTAAGTTTGAGCCACCGATCACTAATGGTGTTGGCTCCCGTAT<SEQ ID NO 631 IL6 - 13F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGTCGTGGTTCGCCGTTTACTGACGTTCCAGTTGCCAAGAGCAGGTGTGACGGAT<SEQ ID NO 632 IL6 - 13R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTGGCAACTGGAACGTCAGTAAACGGCGAACCACGACTGGTGTTGGCTCCCGTAT<SEQ ID NO 633 IL6 - 14F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAATGGTTTTCCTACGACAAGAATAGAAAAATTGCCGAAGAGCAGGTGTGACGGAT<SEQ ID NO 634 IL6 - 14R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTCGGCAATTTTTCTATTCTTGTCGTAGGAAAACCATTGGTGTTGGCTCCCGTAT<SEQ ID NO 635 IL6 - 15F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACTTCATCTTCTGTACTTTATTTGGCAGACCCCTCCCAGAGCAGGTGTGACGGAT<SEQ ID NO 636 IL6 - 15R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGGGAGGGGTCTGCCAAATAAAGTACAGAAGATGAAGTGGTGTTGGCTCCCGTAT<SEQ ID NO 637 IL6 - 16F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACCTTTTAAAACGCTAGCTAGCTTATCCATTCCACCAGAGCAGGTGTGACGGAT<SEQ ID NO 638 IL6 - 16R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGGTGGAATGGATAAGCTAGCTAGCGTTTTAAAAGGTGGTGTTGGCTCCCGTAT<SEQ ID NO 639 IL6 - 17F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGATAGTGTTCCACCTTATACGGAGCCCCCTCACTGAAGAGCAGGTGTGACGGAT<SEQ ID NO 640 IL6 - 17R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTCAGTGAGGGGGCTCCGTATAAGGTGGAACACTATCTGGTGTTGGCTCCCGTAT<SEQ ID NO 641 IL6 - 18F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAACGCACATCAGGAGAATGAAGAACTCACCCCCCCCCAGAGCAGGTGTGACGGAT<SEQ ID NO 642 IL6 - 18R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGGGGGGGGGTGAGTTCTTCATTCTCCTGATGTGCGTTGGTGTTGGCTCCCGTAT<SEQ ID NO 643 IL6 - 19F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACTAACATGCGCGAGGGCTCTGTCCCCGTCCGACATCAGAGCAGGTGTGACGGAT<SEQ ID NO 644 IL6 - 19R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGATGTCGGACGGGGACAGAGCCCTCGCGCATGTTAGTGGTGTTGGCTCCCGTAT<SEQ ID NO 645 IL6 - 21F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAACCTGGCTATCTGCATGCGGTCGGTCGCCTTGTTGGAGAGCAGGTGTGACGGAT<SEQ ID NO 646 IL6 - 21R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCCAACAAGGCGACCGACCGCATGCAGATAGCCAGGTTGGTGTTGGCTCCCGTAT<SEQ ID NO 647 IL6 - 22F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACGTACCCTCAACCTTTAACTTCTCATAACCGGCTGTAGAGCAGGTGTGACGGAT<SEQ ID NO 648 IL6 - 22R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTACAGCCGGTTATGAGAAGTTAAAGGTTGAGGGTACGTGGTGTTGGCTCCCGTAT<SEQ ID NO 649 IL6 - 23F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATGCGTGCCTAATGCCGGCCATTCTACTGCTTGGCCTAGAGCAGGTGTGACGGAT<SEQ ID NO 650 IL6 - 23R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTAGGCCAAGCAGTAGAATGGCCGGCATTAGGCACGCATGGTGTTGGCTCCCGTAT<SEQ ID NO 651 IL6 - 24F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATGTGTACTAATGTAGCTGTTGCAACGTTCCTAACTTAGAGCAGGTGTGACGGAT<SEQ ID NO 652 IL6 - 24R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTAAGTTAGGAACGTTGCAACAGCTACATTAGTACACATGGTGTTGGCTCCCGTAT<SEQ ID NO 653 IL6 - 25F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACTGGTGAGGCGCCTGCGCCGACTGGCCGTCCCCCCGAGAGCAGGTGTGACGGAT<SEQ ID NO 654 IL6 - 25R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCGGGGGGACGGCCAGTCGGCGCAGGCGCCTCACCAGTGGTGTTGGCTCCCGTAT<SEQ ID NO 655 IL18 - 2F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGGGGGCCTCGTTCTACGAGCCTGGGTGTGTCCCTCCAGAGCAGGTGTGACGGAT<SEQ ID NO 656 IL18 - 2R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGGAGGGACACACCCAGGCTCGTAGAACGAGGCCCCCTGGTGTTGGCTCCCGTAT<SEQ ID NO 657 IL18 - 3F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATTGCTGGGCCCACCTATCGGCGTACCGAACCCCCGCAGAGCAGGTGTGACGGAT<SEQ ID NO 658 IL18 - 3R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGCGGGGGTTCGGTACGCCGATAGGTGGGCCCAGCAATGGTGTTGGCTCCCGTAT<SEQ ID NO 659 IL18 - 4F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACGCCGGGACCCCCCCACGATGGCTGCCTATATGTCCAGAGCAGGTGTGACGGAT<SEQ ID NO 660 IL18 - 4R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGGACATATAGGCAGCCATCGTGGGGGGGTCCCGGCGTGGTGTTGGCTCCCGTAT<SEQ ID NO 661 IL18 - 5F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACCCTACTTATCATGTCCTTATCCCGCCTTACTGGCCAGAGCAGGTGTGACGGAT<SEQ ID NO 662 IL18 - 5R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGGCCAGTAAGGCGGGATAAGGACATGATAAGTAGGGTGGTGTTGGCTCCCGTAT<SEQ ID NO 663 IL18 - 7F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATTACCACTCCTTACTTGTACGTGACCTTGTACCACCAGAGCAGGTGTGACGGAT<SEQ ID NO 664 IL18 - 7R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGGTGGTACAAGGTCACGTACAAGTAAGGAGTGGTAATGGTGTTGGCTCCCGTAT<SEQ ID NO 665 IL18 - 8F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATTCCTGCTAACTTGCTGCCTGCCCTCCACGGGGCTCAGAGCAGGTGTGACGGAT<SEQ ID NO 666 IL18 - 8R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGAGCCCCGTGGAGGGCAGGCAGCAAGTTAGCAGGAATGGTGTTGGCTCCCGTAT<SEQ ID NO 667 IL18 - 10F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATCTCATGGTAGCTGCGCTGGTTTTGTGCGTGATATTAGAGCAGGTGTGACGGAT<SEQ ID NO 668 IL18 - 10R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTAATATCACGCACAAAACCAGCGCAGCTACCATGAGATGGTGTTGGCTCCCGTAT<SEQ ID NO 669 IL18 - 11F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATGTAAACTTTCAGGTTGGATAGTACGGGCTCACACAAGAGCAGGTGTGACGGAT<SEQ ID NO 670 IL18 - 11R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTGTGTGAGCCCGTACTATCCAACCTGAAAGTTTACATGGTGTTGGCTCCCGTAT<SEQ ID NO 671 IL18 - 15F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATGTGTCCGCCCTTGTTTTTGTGTCGTCCGGCAATCGAGAGCAGGTGTGACGGAT<SEQ ID NO 672 IL18 - 15R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCGATTGCCGGACGACACAAAAACAAGGGCGGACACATGGTGTTGGCTCCCGTAT<SEQ ID NO 673 IL18 - 16F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGCAGCATAACGTCCGTATCCCAATCCATGACGATCAGAGCAGGTGTGACGGAT<SEQ ID NO 674 IL18 - 16R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGATCGTCATGGATTGGGATACGGACGTTATGCTGCTGGTGTTGGCTCCCGTAT<SEQ ID NO 675 IL18 - 18F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATTTAGGATAAGTGGTCACGCCGTCTCGATTTAACTGAGAGCAGGTGTGACGGAT<SEQ ID NO 676 IL18 - 18R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCAGTTAAATCGAGACGGCGTGACCACTTATCCTAAATGGTGTTGGCTCCCGTAT<SEQ ID NO 677 IL18 - 19F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAATTCCGTATCCATGCTCTGGCTGCGTATCCCCTTTGAGAGCAGGTGTGACGGAT<SEQ ID NO 678 IL18 - 19R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCAAAGGGGATACGCAGCCAGAGCATGGATACGGAATTGGTGTTGGCTCCCGTAT<SEQ ID NO 679 IL18 - 21F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGGAACCGGAATAGGGAATCCCCCTTACCAACCCCCCAGAGCAGGTGTGACGGAT<SEQ ID NO 680 IL18 - 21R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGGGGGGTTGGTAAGGGGGATTCCCTATTCCGGTTCCTGGTGTTGGCTCCCGTAT<SEQ ID NO 681 IL18 - 22F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGAACACCGCCCCCTGTCTGTTCCAATTGCTGTTATCAGAGCAGGTGTGACGGAT<SEQ ID NO 682 IL18 - 22R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGATAACAGCAATTGGAACAGACAGGGGGCGGTGTTCTGGTGTTGGCTCCCGTAT<SEQ ID NO 683 IL18 - 24F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACCCGGTTTTAACTTTTGTTGGTATGTCTCGAATCCCAGAGCAGGTGTGACGGAT<SEQ ID NO 684 IL18 - 24R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGGGATTCGAGACATACCAACAAAAGTTAAAACCGGGTGGTGTTGGCTCCCGTAT<SEQ ID NO 685 IL18 - 26F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAAATAGAGTATTCGAAAGTAGCGTACTTCAGGTCCTAGAGCAGGTGTGACGGAT<SEQ ID NO 686 IL18 - 26R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTAGGACCTGAAGTACGCTACTTTCGAATACTCTATTTGGTGTTGGCTCCCGTAT<SEQ ID NO 687 IL18 - 27/31F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACCGAATTGATTGATAAAAAGGGTTAGATCGCTCCAGAGCAGGTGTGACGGAT<SEQ ID NO 688 IL18 - 27/31R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGGAGCGATCTAACCCTTTTTATCAATCAATTCGGTGGTGTTGGCTCCCGTAT<SEQ ID NO 689 IL18 28F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATTGGCGACAGAGTTCGACGTCCCCTAGTGGCAGAGAGAGCAGGTGTGACGGAT<SEQ ID NO 690 IL18 - 28R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCTCTGCCACTAGGGGACGTCGAACTCTGTCGCCAATGGTGTTGGCTCCCGTAT<SEQ ID NO 691 IL18 - 29F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAATCGCTCTCACAAATTTGCCCTAGACTCATACCATCAGAGCAGGTGTGACGGAT<SEQ ID NO 692 IL18 - 29R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGATGGTATGAGTCTAGGGCAAATTTGTGAGAGCGATTGGTGTTGGCTCCCGTAT<SEQ ID NO 693 IL18 - 30F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCCACACCACAACTTTGAAGATCCTTGAGCCGCGCTCACCACCTAGAGCAGGTGTGACGGAT<SEQ ID NO 694 IL18 - 30R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTAGGTGGTGAGCGCGGCTCAAGGATCTTCAAAGTTGTGGTGTGGGCTCCCGTAT<SEQ ID NO 695 IL18 - 32/33F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACAAAGTTTAGCGTTATGCAACTCCCCCTTATACTCGAGAGCAGGTGTGACGGAT<SEQ ID NO 696 IL18 - 32/33R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCGAGTATAAGGGGGAGTTGCATAACGCTAAACTTTGTGGTGTTGGCTCCCGTAT<SEQ ID NO 697 IL18 - 33F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACAAAGTTTAGCGTTATGCAACTCCCCCTTATACTCGAGAGCAGGTGTGACGGAT<SEQ ID NO 698 IL18 - 33R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCGAGTATAAGGGGGAGTTGCATAACGCTAAACTTTGTGGTGTTGGCTCCCGTAT<SEQ ID NO 699 IL18 - 35F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATACGGCTATACCCGCCCGACGTACACCACATCCCCAGAGCAGGTGTGACGGAT<SEQ ID NO 700 IL18 - 35R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGGGGATGTGGTGTACGTCGGGCGGGTATAGCCGTATGGTGTTGGCTCCCGTAT<SEQ ID NO 701 Myo 1F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGTGTAACTTGGAGCCCTGACGAGCTCTTCCCGTAGCAGAGCAGGTGTGACGGAT<SEQ ID NO 702 Myo 1R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGCTACGGGAAGAGCTCGTCAGGGCTCCAAGTTACACTGGTGTTGGCTCCCGTAT<SEQ ID NO 703 Myo 3F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATAGTTTAGCATGCTCAATAGTACACCAGATCAGTGGAGAGCAGGTGTGACGGAT<SEQ ID NO 704 Myo 3R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCCACTGATCTGGTGTACTATTGAGCATGCTAAACTATGGTGTTGGCTCCCGTAT<SEQ ID NO 705 Myo 4F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATTCGTGTGTCTGTCTAAGTGGAACTGCCTGTAATTAAGAGCAGGTGTGACGGAT<SEQ ID NO 706 Myo 4R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTAATTACAGGCAGTTCCACTTAGACAGACACACGAATGGTGTTGGCTCCCGTAT<SEQ ID NO 707 Myo 5F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACATGAGTGGCGGGCTTAGCGGGCTGCAAGGCGCGTTAGAGCAGGTGTGACGGAT<SEQ ID NO 708 Myo 5R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTAACGCGCCTTGCAGCCCGCTAAGCCCGCCACTCATGTGGTGTTGGCTCCCGTAT<SEQ ID NO 709 Myo 6F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATGTGGCATAAACAGACGAATTTGTCCTATAACGAGTAGAGCAGGTGTGACGGAT<SEQ ID NO 710 Myo 6R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTACTCGTTATAGGACAAATTCGTCTGTTTATGCCACATGGTGTTGGCTCCCGTAT<SEQ ID NO 711 Myo 7F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACTTATTACCGATTTAGCTTGAGACTCCTCCCCTACAAGAGCAGGTGTGACGGAT<SEQ ID NO 712 Myo 7R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTGTAGGGGAGGAGTCTCAAGCTAAATCGGTAATAAGTGGTGTTGGCTCCCGTAT<SEQ ID NO 713 Myo 8F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATCGTTTTGTACTTTATGAGCCGCACGGAGCCCCCCCAGAGCAGGTGTGACGGAT <SEQ ID NO 714 Myo 8R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGGGGGGGCTCCGTGCGGCTCATAAAGTACAAAACGATGGTGTTGGCTCCCGTAT<SEQ ID NO 715 Myo 9F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATCTCGCTAAGCTCTGTTGGGACTAACTTCCGCTATTAGAGCAGGTGTGACGGAT<SEQ ID NO 716 Myo 9R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTAATAGCGGAAGTTAGTCCCAACAGAGCTTAGCGAGATGGTGTTGGCTCCCGTAT<SEQ ID NO 717 Myo 11F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATCCACCCTACGTCATAATATGAAATGAAACATATATAGAGCAGGTGTGACGGAT<SEQ ID NO 718 Myo 11R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTATATATGTTTCATTTCATATTATGACGTAGGGTGGATGGTGTTGGCTCCCGTAT<SEQ ID NO 719 Myo 12F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACCCACTCTCCCCCCGCTCCCGCTCCCCCGCTCCGCGAGAGCAGGTGTGACGGAT<SEQ ID NO 720 Myo 12R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCGCGGAGCGGGGGAGCGGGAGCGGGGGGAGAGTGGGTGGTGTTGGCTCCCGTAT<SEQ ID NO 721 Myo 13F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAATAGTTGCGTCTTGTCATGTACGCCTCCTTGCCAGCAGAGCAGGTGTGACGGAT<SEQ ID NO 722 Myo 13R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGCTGGCAAGGAGGCGTACATGACAAGACGCAACTATTGGTGTTGGCTCCCGTAT<SEQ ID NO 723 Myo 14F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGCGGGTTTCTTAGTTCTGATTGGACGCTCTGTTTGCAGAGCAGGTGTGACGGAT<SEQ ID NO 724 Myo 14R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGCAAACAGAGCGTCCAATCAGAACTAAGAAACCCGCTGGTGTTGGCTCCCGTAT<SEQ ID NO 725 Myo 15F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAAGAGCACCTGCACCCTCCCGCCCTCTATTGCATTCTAGAGCAGGTGTGACGGAT<SEQ ID NO 726 Myo 15R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTAGAATGCAATAGAGGGCGGGAGGGTGCAGGTGCTCTTGGTGTTGGCTCCCGTAT<SEQ ID NO 727 Myo - 17F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACATCATACCTTGTTCTACCGGCAGCCTCTCTAAATAAGAGCAGGTGTGACGGAT<SEQ ID NO 728 Myo - 17R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTATTTAGAGAGGCTGCCGGTAGAACAAGGTATGATGTGGTGTTGGCTCCCGTAT<SEQ ID NO 729 Myo - 18F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATTCCAAATGAACAGTTCTCGATCCCACTTCTCATCTAGAGCAGGTGTGACGGAT<SEQ ID NO 730 Myo - 18R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTAGATGAGAAGTGGGATCGAGAACTGTTCATTTGGAATGGTGTTGGCTCCCGTAT<SEQ ID NO 731 Myo - 19F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGACCTACTGCCCCCCTGTCTCCCTTTGTCTGCCCTTAGAGCAGGTGTGACGGAT<SEQ ID NO 732 Myo - 19R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTAAGGGCAGACAAAGGGAGACAGGGGGGCAGTAGGTCTGGTGTTGGCTCCCGTAT<SEQ ID NO 733 Myo - 20F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAACCATCCCGGAATGTGGGTTTTATGTAAATATAAGCAGAGCAGGTGTGACGGAT<SEQ ID NO 734 Myo - 20R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGCTTATATTTACATAAAACCCACATTCCGGGATGGTTGGTGTTGGCTCCCGTAT<SEQ ID NO 735 Myo - 21F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACCCCTAACTCCTATATTTAATCCTTATCAAATTTCTAGAGCAGGTGTGACGGAT<SEQ ID NO 736 Myo - 21R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTAGAAATTTGATAAGGATTAAATATAGGAGTTAGGGGTGGTGTTGGCTCCCGTAT<SEQ ID NO 737 Myo - 22F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACCAGCAGTAAAGTTCCAGCATTGCGCTTAATAGACTAGAGCAGGTGTGACGGAT<SEQ ID NO 738 Myo - 22R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTAGTCTATTAAGCGCAATGCTGGAACTTTACTGCTGGTGGTGTTGGCTCCCGTAT<SEQ ID NO 739 Myo - 23F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAAGTCCAAGCCAAACAAGAGCATAACACCAAATCTGGAGAGCAGGTGTGACGGAT<SEQ ID NO 740 Myo - 23R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCCAGATTTGGTGTTATGCTCTTGTTTGGCTTGGACTTGGTGTTGGCTCCCGTAT<SEQ ID NO 741 Myo - 24F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACTCAATACGTCTTATCGTCTCTGAGTACATCTGGCCAGAGCAGGTGTGACGGAT<SEQ ID NO 742 Myo - 24R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGGCCAGATGTACTCAGAGACGATAAGACGTATTGAGTGGTGTTGGCTCCCGTAT<SEQ ID NO 743 Myo - 25F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGGGCCGCTGCGATTTCTACGCTACCTGCCGTTGGTAAGAGCAGGTGTGACGGAT<SEQ ID NO 744 Myo - 25R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTACCAACGGCAGGTAGCGTAGAAATCGCAGCGGCCCTGGTGTTGGCTCCCGTAT<SEQ ID NO 745 Myo - 26F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACAACCGGCTAATGACAAATCAAAGATTTTTTCGGCGAGAGCAGGTGTGACGGAT<SEQ ID NO 746 Myo - 26R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCGCCGAAAAAATCTTTGATTTGTCATTAGCCGGTTGTGGTGTTGGCTCCCGTAT<SEQ ID NO 747 Myo - 27F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGCACAACTTAAGTGCAAGCAAATTCGGATTAACCAAAGAGCAGGTGTGACGGAT<SEQ ID NO 748 Myo - 27R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTTGGTTAATCCGAATTTGCTTGCACTTAAGTTGTGCTGGTGTTGGCTCCCGTAT<SEQ ID NO 749 Myo - 28F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATCCGAACAGTTAGTTTAAGACCGTCCTCCTTTCTTAAGAGCAGGTGTGACGGAT<SEQ ID NO 750 Myo - 28R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTAAGAAAGGAGGACGGTCTTAAACTAACTGTTCGGATGGTGTTGGCTCCCGTAT<SEQ ID NO 751 Myo - 29F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACTTCAAAAGTCAGATACAAAGACAGAGATTGGACTTAGAGCAGGTGTGACGGAT<SEQ ID NO 752 Myo - 29R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTAAGTCCAATCTCTGTCTTTGTATCTGACTTTTGAAGTGGTGTTGGCTCCCGTAT<SEQ ID NO 753 Myo - 30F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACTTCCGTTATAACGTTTCTGGAATTTACTACGATTAGAGCAGGTGTGACGGAT<SEQ ID NO 754 Myo - 30R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTAATCGTAGTAAATTCCAGAAACGTTATAACGGAAGTGGTGTTGGCTCCCGTAT<SEQ ID NO 755 Tpn - 1F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAACCACGGATGTTGAATATCCGACGATCACGTAATTAGAGCAGGTGTGACGGAT<SEQ ID NO 756 Tpn - 1R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTAATTACGTGATCGTCGGATATTCAACATCCGTGGTTGGTGTTGGCTCCCGTAT<SEQ ID NO 757 Tpn - 2F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATAGACTTAAGCTCTCTCCAGGAGCTTGTCGCTTGCAGAGCAGGTGTGACGGAT<SEQ ID NO 758 Tpn - 2R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGCAAGCGACAAGCTCCTGGAGAGAGCTTAAGTCTATGGTGTTGGCTCCCGTAT<SEQ ID NO 759 Tpn - 3F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACGGGGGCATCTTCCATTAACCCATTACCTCACCCCAAGAGCAGGTGTGACGGAT<SEQ ID NO 760 Tpn - 3R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTGGGGTGAGGTAATGGGTTAATGGAAGATGCCCCCGTGGTGTTGGCTCCCGTAT<SEQ ID NO 761 Tpn - 4aF; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACACAGACAACCATTGATTACGGGGACAATTCGGGCAGAGCAGGTGTGACGGAT<SEQ ID NO 762 Tpn - 4aR; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGCCCGAATTGTCCCCGTAATCAATGGTTGTCTGTGTGGTGTTGGCTCCCGTAT<SEQ ID NO 763 Tpn - 4bF; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACTGGTAGGTGAGTGTGTGTCTGTACTCGCATCGTTAGAGCAGGTGTGACGGAT<SEQ ID NO 764 Tpn - 4bR; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTAACGATGCGAGTACAGACACACACTCACCTACCAGTGGTGTTGGCTCCCGTAT<SEQ ID NO 765 Tpn - 5/19F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACCGAATTGATTGATAAAAAGGGTTAGATCGCTCCAGAGCAGGTGTGACGGAT<SEQ ID NO 766 Tpn - 5/19R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGGAGCGATCTAACCCTTTTTATCAATCAATTCGGTGGTGTTGGCTCCCGTAT<SEQ ID NO 767 Tpn - 6F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACCTAGGCCCCCAACATGTGTGGTATAAGTTTCCGTAGAGCAGGTGTGACGGAT<SEQ ID NO 768 Tpn - 6R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTACGGAAACTTATACCACACATGTTGGGGGCCTAGGTGGTGTTGGCTCCCGTAT<SEQ ID NO 769 Tpn - 7F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATCAGAAACTATAGTGCCATAGTTTTATCTTTGTACAGAGCAGGTGTGACGGAT<SEQ ID NO 770 Tpn - 7R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGTACAAAGATAAAACTATGGCACTATAGTTTCTGATGGTGTTGGCTCCCGTAT<SEQ ID NO 771 Tpn - 8F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAATAGATGGATAAGGGGGAAACTGCCATTCGGTTAGTAGAGCAGGTGTGACGGAT<SEQ ID NO 772 Tpn - 8R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTACTAACCGAATGGCAGTTTCCCCCTTATCCATCTATTGGTGTTGGCTCCCGTAT<SEQ ID NO 773 Tpn - 9F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACCAACGAATACTACCAGGCCTAGCACAATACACAACAGAGCAGGTGTGACGGAT<SEQ ID NO 774 Tpn - 9R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGTTGTGTATTGTGCTAGGCCTGGTAGTATTCGTTGGTGGTGTTGGCTCCCGTAT<SEQ ID NO 775 Tpn - 10F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAAACTTGAGATATGGGCGCTATGTTCCTTTTCATCCAGAGCAGGTGTGACGGAT<SEQ ID NO 776 Tpn - 10R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGGATGAAAAGGAACATAGCGCCCATATCTCAAGTTTGGTGTTGGCTCCCGTAT<SEQ ID NO 777 Tpn - 11F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGCCGACCGGTAAGTTTATATAAACTTCCGCCGCCTAGAGCAGGTGTGACGGAT<SEQ ID NO 778 Tpn - 11R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTAGGCGGCGGAAGTTTATATAAACTTACCGGTCGGCTGGTGTTGGCTCCCGTAT<SEQ ID NO 779 Tpn - 12F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATGACTCACGCTTCTCGCCCGCACGAAGAGTCTCCAAGAGCAGGTGTGACGGAT<SEQ ID NO 780 Tpn - 12R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTGGAGACTCTTCGTGCGGGCGAGAAGCGTGAGTCATGGTGTTGGCTCCCGTAT<SEQ ID NO 781 Tpn - 13F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATGACGACCATGCAAGAAATCCGACAATTCCTCACGAGAGCAGGTGTGACGGAT<SEQ ID NO 782 Tpn - 13R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCGTGAGGAATTGTCGGATTTCTTGCATGGTCGTCATGGTGTTGGCTCCCGTAT<SEQ ID NO 783 Tpn - 14F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAAGCATTTAGATTCGCTCCTTGAACCCACTTCCTTCAGAGCAGGTGTGACGGAT<SEQ ID NO 784 Tpn - 14R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGAAGGAAGTGGGTTCAAGGAGCGAATCTAAATGCTTGGTGTTGGCTCCCGTAT<SEQ ID NO 785 Tpn - 15F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGGTGCTTCTCTTACGTGGCCGCTATTCCAAAGTGAAGAGCAGGTGTGACGGAT<SEQ ID NO 786 Tpn - 15R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTCACTTTGGAATAGCGGCCACGTAAGAGAAGCACCTGGTGTTGGCTCCCGTAT<SEQ ID NO 787 Tpn - 16F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGCCCGGGCATGTCGTTTGTATGAAGCTAGCTAACTAGAGCAGGTGTGACGGAT<SEQ ID NO 788 Tpn - 16R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTAGTTAGCTAGCTTCATACAAACGACATGCCCGGGCTGGTGTTGGCTCCCGTAT<SEQ ID NO 789 Tpn - 17F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATGACCATCAATACAGACAAATAGAATCGCGTTATGAGAGCAGGTGTGACGGAT<SEQ ID NO 790 Tpn - 17R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCATAACGCGATTCTATTTGTCTGTATTGATGGTCATGGTGTTGGCTCCCGTAT<SEQ ID NO 791 Tpn - 18F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATGAGGGTTTCCTCACATGGGGAGGTCCTCCATGTGGAGAGCAGGTGTGACGGAT<SEQ ID NO 792 Tpn - 18R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCCACATGGAGGACCTCCCCATGTGAGGAAACCCTCATGGTGTTGGCTCCCGTAT<SEQ ID NO 793 Tpn - 20F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGGACTAACATTATAAGAATTGCGAATAATCATTGGAGAGCAGGTGTGACGGAT<SEQ ID NO 794 Tpn - 20R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCCAATGATTATTCGCAATTCTTATAATGTTAGTCCTGGTGTTGGCTCCCGTAT<SEQ ID NO 795 DD - 1F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATTGTACCTTAACTATACTCAGCTACATTATGCCAAAGAGCAGGTGTGACGGAT<SEQ ID NO 796 DD - 1R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTTGGCATAATGTAGCTGAGTATAGTTAAGGTACAATGGTGTTGGCTCCCGTAT<SEQ ID NO 797 DD - 2F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACTCATGTTGGATATTACGAACAGTGCGTTAGGCTGAGAGCAGGTGTGACGGAT<SEQ ID NO 798 DD - 2R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCAGCCTAACGCACTGTTCGTAATATCCAACATGAGTGGTGTTGGCTCCCGTAT<SEQ ID NO 799 DD - 3F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATGAACGCATCACAGTTGCTTCACACTCGACTAGCTAGAGCAGGTGTGACGGAT<SEQ ID NO 800 DD - 3R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTAGCTAGTCGAGTGTGAAGCAACTGTGATGCGTTCATGGTGTTGGCTCCCGTAT<SEQ ID NO 801 DD - 4F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAAAAACTACTCTCTACGGATCGTACATCATGGGCGTAGAGCAGGTGTGACGGAT<SEQ ID NO 802 DD - 4R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTACGCCCATGATGTACGATCCGTAGAGAGTAGTTTTTGGTGTTGGCTCCCGTAT<SEQ ID NO 803 DD - 5F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACCCACTCTCCCCCCGCTCCCGCTCCCCCGCTCCGCGAGAGCAGGTGTGACGGAT<SEQ ID NO 804 DD - 5R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCGCGGAGCGGGGGAGCGGGAGCGGGGGGAGAGTGGGTGGTGTTGGCTCCCGTAT<SEQ ID NO 805 DD - 6F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATAGGGCAATTAAGGCCAAGAGTGTTGGCCGTCGCTAGAGCAGGTGTGACGGAT<SEQ ID NO 806 DD - 6R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTAGCGACGGCCAACACTCTTGGCCTTAATTGCCCTATGGTGTTGGCTCCCGTAT<SEQ ID NO 807 DD - 7F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAAAACGGGAAACTGCATTTCCCACGCCTCGTACCCCAGAGCAGGTGTGACGGAT<SEQ ID NO 808 DD - 7R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGGGGTACGAGGCGTGGGAAATGCAGTTTCCCGTTTTGGTGTTGGCTCCCGTAT<SEQ ID NO 809 DD - 9F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAAACCGAAGGATCGCCGGGTCAGACCTATCTCAAGCAGAGCAGGTGTGACGGAT<SEQ ID NO 810 DD - 9R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGCTTGAGATAGGTCTGACCCGGCGATCCTTCGGTTTGGTGTTGGCTCCCGTAT<SEQ ID NO 811 DD - 10F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATTTGCTGACGAACCATTGGCTAGCTTGATTGTCACAGAGCAGGTGTGACGGAT<SEQ ID NO 812 DD - 10R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGTGACAATCAAGCTAGCCAATGGTTCGTCAGCAAATGGTGTTGGCTCCCGTAT<SEQ ID NO 813 DD - 11F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGACTTTTTGCTGCCATCCCGGGTGTCGTTGCAAGTAGAGCAGGTGTGACGGAT<SEQ ID NO 814 DD - 11R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTACTTGCAACGACACCCGGGATGGCAGCAAAAAGTCTGGTGTTGGCTCCCGTAT<SEQ ID NO 815 DD - 12F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACGCATCCCCCGCCGGGCCCGCGCCCCGCTCGCAGACAGAGCAGGTGTGACGGAT<SEQ ID NO 816 DD - 12R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGTCTGCGAGCGGGGCGCGGGCCCGGCGGGGGATGCGTGGTGTTGGCTCCCGTAT<SEQ ID NO 817 DD - 13F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACAATCATTAAACCTTTTTACTCTTCCTGAATCACCAGAGCAGGTGTGACGGAT<SEQ ID NO 818 DD - 13R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGGTGATTCAGGAAGAGTAAAAAGGTTTAATGATTGTGGTGTTGGCTCCCGTAT<SEQ ID NO 819 DD - 14F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAACTTATGCGACCCTTCCGGTAGCTGGAGGTTATTAAGAGCAGGTGTGACGGAT<SEQ ID NO 820 DD 14R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTAATAACCTCCAGCTACCGGAAGGGTCGCATAAGTTGGTGTTGGCTCCCGTAT<SEQ ID NO 821 DD - 15F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGGGCCGCCTCTTTCCGATTCGTGGGAGCCTTCTTGAAGAGCAGGTGTGACGGAT<SEQ ID NO 822 DD - 15R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTCAAGAAGGCTCCCACGAATCGGAAAGAGGCGGCCCTGGTGTTGGCTCCCGTAT<SEQ ID NO 823 DD - 16F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATGTTCCGTCACAGGTCTCCTGTTCTTAATTTGTTTTAGAGCAGGTGTGACGGAT<SEQ ID NO 824 DD - 16R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTAAAACAAATTAAGAACAGGAGACCTGTGACGGAACATGGTGTTGGCTCCCGTAT<SEQ ID NO 825 DD - 17F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATACGACCTGGAAACTGCTCGTCAGAGTCTGAAATGAGAGCAGGTGTGACGGAT<SEQ ID NO 826 DD - 17R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCATTTCAGACTCTGACGAGCAGTTTCCAGGTCGTATGGTGTTGGCTCCCGTAT<SEQ ID NO 827 DD - 19F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAAGTTGTCACTGGATGACATTCGGGTTCGCTTGCACAGAGCAGGTGTGACGGAT<SEQ ID NO 828 DD - 19R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGTGCAAGCGAACCCGAATGTCATCCAGTGACAACTTGGTGTTGGCTCCCGTAT<SEQ ID NO 829 DD - 20F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAAAGTGGATTGCGACGTGCTTCTACCAGATACCCGGAGAGCAGGTGTGACGGAT<SEQ ID NO 830 DD - 20R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCCGGGTATCTGGTAGAAGCACGTCGCAATCCACTTTGGTGTTGGCTCCCGTAT<SEQ ID NO 831 MBI - 1/4/5/8/9/17F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGCACACGGCACGCCCCTCCGAACCACGCCCCCGAAAGAGCAGGTGTGACGGAT<SEQ ID NO 832 MBI - 1/4/5/8/9/17R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTTCGGGGGCGTGGTTCGGAGGGGCGTGCCGTGTGCTGGTGTTGGCTCCCGTAT<SEQ ID NO 833 MBI - 2F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGCGACGACAGTTATATAATCCGAGAATAGTACATGAGAGCAGGTGTGACGGAT<SEQ ID NO 834 MBI - 2R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCATGTACTATTCTCGGATTATATAACTGTCGTCGCTGGTGTTGGCTCCCGTAT<SEQ ID NO 835 MBI - 3F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGCACACGGCACGCCCCCCGAACCACGCCCCCGAAAGAGCAGGTGTGACGGAT<SEQ ID NO 836 MBI - 3R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTTCGGGGGCGTGGTTCGGGGGGCGTGCCGTGTGCTGGTGTTGGCTCCCGTAT<SEQ ID NO 837 MBI - 6F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATATTTCAATCTGTTGAAATAATTCATACATGCTTAAGAGCAGGTGTGACGGAT<SEQ ID NO 838 MBI - 6R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTAAGCATGTATGAATTATTTCAACAGATTGAAATATGGTGTTGGCTCCCGTAT<SEQ ID NO 839 MBI - 7/13F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATCCTCCTGCGACGTCTGGAGAACAGCCTCTACTTTAAGAGCAGGTGTGACGGAT<SEQ ID NO 840 MBI - 7/13R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTAAAGTAGAGGCTGTTCTCCAGACGTCGCAGGAGGATGGTGTTGGCTCCCGTAT<SEQ ID NO 841 MBI - 10F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGGCTGCGTACATGAACAGGCACTACAAATGTCCCAAGAGCAGGTGTGACGGAT<SEQ ID NO 842 MBI - 10R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTGGGACATTTGTAGTGCCTGTTCATGTACGCAGCCTGGTGTTGGCTCCCGTAT<SEQ ID NO 843 MBI - 11F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACAGAGAGAAGTACGTAACATCAAAAACGCGGTCAGAAGAGCAGGTGTGACGGAT<SEQ ID NO 844 MBI - 11R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTCTGACCGCGTTTTTGATGTTACGTACTTCTCTCTGTGGTGTTGGCTCCCGTAT<SEQ ID NO 845 MBI - 12F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAACACAACCGAGCCAATAGACAATCAGTGTTTCACAGAGCAGGTGTGACGGAT<SEQ ID NO 846 MBI - 12R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGTGAAACACTGATTGTCTATTGGCTCGGTTGTGTTGGTGTTGGCTCCCGTAT<SEQ ID NO 847 MBI - 14/18F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACCCTAAATTCCAGAGTGTACAAGAGAACGAACTACCAGAGCAGGTGTGACGGAT<SEQ ID NO 848 MBI - 14/18R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGGTAGTTCGTTCTCTTGTACACTCTGGAATTTAGGGTGGTGTTGGCTCCCGTAT<SEQ ID NO 849 MBI - 15F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAATAGATGGATAAGGGGGAAACTGCCATTCGGTTAGTAGAGCAGGTGTGACGGAT<SEQ ID NO 850 MBI - 15R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTACTAACCGAATGGCAGTTTCCCCCTTATCCATCTATTGGTGTTGGCTCCCGTAT<SEQ ID NO 851 MBI - 16F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAAAACCCGCACTACATCTCCTCTGCCCCCTTCTGATAAGAGCAGGTGTGACGGAT<SEQ ID NO 852 MBI - 16R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTATCAGAAGGGGGCAGAGGAGATGTAGTGCGGGTTTTGGTGTTGGCTCCCGTAT<SEQ ID NO 853 MBI - 19F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATCGAATGGTCTCCCAACTAAAGAAACTCTCCATCCAGAGCAGGTGTGACGG<SEQ ID NO 854 MBI - 19R; DNA; SYNTHETIC OLIGONUCLEOTIDE>CCGTCACACCTGCTCTGGATGGAGAGTTTCTTTAGTTGGGAGACCATTCGATGGTGTTGGCTCCCGTAT<SEQ ID NO 855 MBI - 20F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACGGGGGCATCTTCCATTAACCCATTACCTCACCCCAAGAGCAGGTGTGACGGAT<SEQ ID NO 856 MBI - 20R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTGGGGTGAGGTAATGGGTTAATGGAAGATGCCCCCGTGGTGTTGGCTCCCGTAT<SEQ ID NO 857 MBII - 1F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATGGACGTACTGACTGCCCCGTACTCTTTTCAGTTGAGAGCAGGTGTGACGGAT<SEQ ID NO 858 MBII - 1R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCAACTGAAAAGAGTACGGGGCAGTCAGTACGTCCATGGTGTTGGCTCCCGTAT<SEQ ID NO 859 MBII - 2F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAACTAACTACTCAAGATGAACACTGTCGGCGTTTACAGAGCAGGTGTGACGGAT<SEQ ID NO 860 MBII - 2R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGTAAACGCCGACAGTGTTCATCTTGAGTAGTTAGTTGGTGTTGGCTCCCGTAT<SEQ ID NO 861 MBII - 3F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGCCCTTAAGCGTTGCCTAACGGACTCTGAGGCAATAGAGCAGGTGTGACGGAT<SEQ ID NO 862 MBII - 3R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTATTGCCTCAGAGTCCGTTAGGCAACGCTTAAGGGCTGGTGTTGGCTCCCGTAT<SEQ ID NO 863 MBII - 4F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAACCTCACTTACAACTCGATTTTTTATGGACAGCCGAGAGCAGGTGTGACGGAT<SEQ ID NO 864 MBII - 4R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCGGCTGTCCATAAAAAATCGAGTTGTAAGTGAGGTTGGTGTTGGCTCCCGTAT<SEQ ID NO 865 MBII - 5F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATTTGAGCGGCAGCTAACCGGCCGACCAATTCGCTACAGAGCAGGTGTGACGGAT<SEQ ID NO 866 MBII - 5R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGTAGCGAATTGGTCGGCCGGTTAGCTGCCGCTCAAATGGTGTTGGCTCCCGTAT<SEQ ID NO 867 MBII 6/8F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACCTTTTAAAACGCTAGCTAGCTTAGTCCATTCCACCAGAGCAGGTGTGACGGAT<SEQ ID NO 868 MBII 6/8R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGGTGGAATGGACTAAGCTAGCTAGCGTTTTAAAAGGTGGTGTTGGCTCCCGTAT<SEQ ID NO 869 MBII - 7F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGCCCTGGGCCAGCCCGTGACTTTCCCCCGGCGTCCAAGAGCAGGTGTGACGGAT<SEQ ID NO 870 MBII - 7R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTGGACGCCGGGGGAAAGTCACGGGCTGGCCCAGGGCTGGTGTTGGCTCCCGTAT<SEQ ID NO 871 MBII - 9F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATCCTCCTGCGGCGTCTGGAGAACAGCCTCTACTTTAAGAGCAGGTGTGACGGAT<SEQ ID NO 872 MBII - 9R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTAAAGTAGAGGCTGTTCTCCAGACGCCGCAGGAGGATGGTGTTGGCTCCCGTAT<SEQ ID NO 873 MBII - 10F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACCAACGAATACTACCAGGCCTAGCACAATACACAACAGAGCAGGTGTGACGGAT<SEQ ID NO 874 MBII - 10R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGTTGTGTATTGTGCTAGGCCTGGTAGTATTCGTTGGTGGTGTTGGCTCCCGTAT<SEQ ID NO 875 MBII - 11F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCACCGAATGTGCTGCAAGACTAATCTGGATGGCCATGCAGAGCAGGTGTGACGGAT<SEQ ID NO 876 MBII - 11R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTGCATGGCCATCCAGATTAGTCTTGCAGCACATTCGGTGGTGTTGGCTCCCGTAT<SEQ ID NO 877 MBII - 12F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCATTGAGGGGCTGGGATACTGCAACTTAAAGTCCAGGAGAGCAGGTGTGACGGAT<SEQ ID NO 878 MBII - 12R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCCTGGACTTTAAGTTGCAGTATCCCAGCCCCTCAATGGTGTTGGCTCCCGTAT<SEQ ID NO 879 MBII - 13aF; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAATAAGCGACTAGTGTATTGGTACTGGCCTTTTCCGAGAGCAGGTGTGACGGAT<SEQ ID NO 880 MBII - 13aR; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTCGGAAAAGGCCAGTACCAATACACTAGTCGCTTATTGGTGTTGGCTCCCGTAT<SEQ ID NO 881 MBII - 13bF; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAATCTTACTAGTTTGGGAAAAAAATTAAATATAAGCAAGAGCAGGTGTGACGGAT<SEQ ID NO 882 MBII - 13bR; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTGCTTATATTTAATTTTTTTCCCAAACTAGTAAGATTGGTGTTGGCTCCCGTAT<SEQ ID NO 883 MBII - 14F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGTCCGTTATGACATGTCCGGACCCGTACGCGTGTCAAGAGCAGGTGTGACGGAT<SEQ ID NO 884 MBII - 14R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTGACACGCGTACGGGTCCGGACATGTCATAACGGACTGGTGTTGGCTCCCGTAT<SEQ ID NO 885 MBII - 15F; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATACGGGAGCCAACACCAGGGATTGCATTACCCATGACTAAGAGTAGGTCGCAAGAGCAGGTGTGACGGAT<SEQ ID NO 886 MBII - 15R; DNA; SYNTHETIC OLIGONUCLEOTIDE>ATCCGTCACACCTGCTCTTGCGACCTACTCTTAGTCATGGGTAATGCAATCCCTGGTGTTGGCTCCCGTAT<SEQ ID NO. 887 NAG 13F; DNA; Artificial>ATACGGGAGCCAACACCATAGAAGTATGTTGTTATTCTATGGAAATAAAACGACAGAGCAGGTGTGACGGAT<SEQ ID NO. 888 NAG 13R; DNA; Artificial>ATCCGTCACACCTGCTCTGTCGTTTTATTTCCATAGAATAACAACATACTTCTATGGTGTTGGCTCCCGTAT<SEQ ID NO. 889 NAG 14F; DNA; Artificial>ATACGGGAGCCAACACCATCCCGTTGTGATCAGAGAGCATGAAATGATGTTTTGAGAGCAGGTGTGACGGAT<SEQ ID NO. 890 NAG 14R; DNA; Artificial>ATCCGTCACACCTGCTCTCAAAACATCATTTCATGCTCTCTGATCACAACGGGATGGTGTTGGCTCCCGTAT<SEQ ID NO. 891 NAG 18F; DNA; Artificial>ATACGGGAGCCAACACCATGCATGGGACCTGTTATCCTAACAAGCTGTCAAGGCAGAGCAGGTGTGACGGAT<SEQ ID NO. 892 NAG 18R; DNA; Artificial>ATCCGTCACACCTGCTCTGCCTTGACAGCTTGTTAGGATAACAGGTCCCATGCATGGTGTTGGCTCCCGTAT<SEQ ID NO. 893 NAG 20F; DNA; Artificial>ATACGGGAGCCAACACCACAAAACGTTCCGAGGGAGTAAGCACTTAATAATGTAGAGCAGGTGTGACGGAT<SEQ ID NO. 894 NAG 20R; DNA; Artificial>ATCCGTCACACCTGCTCTACATTATTAAGTGCTTACTCCCTCGGAACGTTTTGTGGTGTTGGCTCCCGTAT<SEQ ID NO. 895 NAG 21F; DNA; Artificial>ATACGGGAGCCAACACCACGTCTTATAGATGTCTGTATTGTTTATCGCTCGCCCAGAGCAGGTGTGACGGAT<SEQ ID NO. 896 NAG 21R; DNA; Artificial>ATCCGTCACACCTGCTCTGGGCGAGCGATAAACAATACAGACATCTATAAGACGTGGTGTTGGCTCCCGTAT<SEQ ID NO. 897 NAG 22F; DNA; Artificial>ATACGGGAGCCAACACCACCATCTCTGGTGATAACCAGTGATCTTAACTATAGCAGAGCAGGTGTGACGGAT<SEQ ID NO. 898 NAG 22R; DNA; Artificial>ATCCGTCACACCTGCTCTGCTATAGTTAAGATCACTGGTTATCACCAGAGATGGTGGTGTTGGCTCCCGTAT<SEQ ID NO. 899 NAG 23F; DNA; Artificial>ATACGGGAGCCAACACCACCACCTCACTACAGTGATCTTTTGCTCTGAATAGCCAGAGCAGGTGTGACGGAT<SEQ ID NO. 900 NAG 23R; DNA; Artificial>ATCCGTCACACCTGCTCTGGCTATTCAGAGCAAAAGATCACTGTAGTGAGGTGGTGGTGTTGGCTCCCGTAT<SEQ ID NO. 901 NAG 25F; DNA; Artificial>ATACGGGAGCCAACACCATGTCTCTTAGGATACAAAGCCAAACTGAGCCCGTGCAGAGCAGGTGTGACGGAT<SEQ ID NO. 902 NAG 25R; DNA; Artificial>ATCCGTCACACCTGCTCTGCACGGGCTCAGTTTGGCTTTGTATCCTAAGAGACATGGTGTTGGCTCCCGTAT<SEQ ID NO. 903 NAG 26F; DNA; Artificial>ATACGGGAGCCAACACCACCTCCAATAGCCAAAAGAAATCGCCAACTAACGGCAAGAGCAGGTGTGACGGAT<SEQ ID NO. 904 NAG 26R; DNA; Artificial>ATCCGTCACACCTGCTCTTGCCGTTAGTTGGCGATTTCTTTTGGCTATTGGAGGTGGTGTTGGCTCCCGTAT<SEQ ID NO. 905 NAG 30F; DNA; Artificial>ATACGGGAGCCAACACCATCACTACTTTTATAATTTCATTCTTCTGGCGTCCCTAGAGCAGGTGTGACGGAT<SEQ ID NO. 906 NAG 30R; DNA; Artificial>ATCCGTCACACCTGCTCTAGGGACGCCAGAAGAATGAAATTATAAAAGTAGTGATGGTGTTGGCTCCCGTAT

1. A DNA ligand sequence consisting of a nucleic acid sequence selectedfrom SEQ ID NOS: 1-906.
 2. A composition comprising the DNA ligandsequence of claim
 1. 3. The composition of claim 2, wherein said aptameris capable of binding to a targeted bone marker consisting ofC-telopeptide (CTx; of the common 8 or 26 amino acid length varieties),helical peptide (HP), hydroxylysine, N-telopeptide (NTx), Osteocalcin orpeptide fragments of Osteocalcin, Pro-Cathepsin K, deoxypyridinoline (DPor DPD), or pyridinoline (Pyd).
 4. The composition of claim 2, whereinsaid aptamer is capable of binding to a targeted human growth hormone(hGH or somatotropin) and its variants including modified forms ofrecombinant hGH (rhGH).
 5. The composition of claim 2, wherein saidaptamer is capable of binding to a targeted metabolite such as D-glucose(dextrose) or creatinine (Cr) from blood or urine.
 6. The composition ofclaim 2, wherein said aptamer is capable of binding to a targetedinterleukin or cytokine.
 7. The composition of claim 2, wherein saidaptamer is capable of binding to a targeted 1-hydroxy-vitamin D2,1-hydroxy-vitamin D3, 25-hydroxy-vitamin D3, or related derivative ofvitamin D.
 8. The composition of claim 2, wherein said aptamer iscapable of binding to a targeted biomarker of cardiovascular importancesuch as BNP, CK-MB, C-Reactive Protein (CRP), D-Dimer, Interleukins 6and 18 (IL-6 and IL-18), Myosin, or Troponin-T.
 9. The composition ofclaim 2, wherein said aptamer is capable of binding to a targetedN-acetylglucosamine (NAG or O-GlcNAc) group added post-translationallyto a protein or a stem cell.
 10. The DNA ligand sequence of claim 1,wherein: said DNA ligand sequence is capable of being used for at leastone of the assay types: ELISA-like, lateral flow chromatographic teststrips or dipsticks, chemiluminescence or electrochemiluminescence(ECL), fluorescence (intensity, lifetime, FP, FRET beacons andcompetitive FRET), magnetic bead capture, membrane blotting (includingdot or slot blotting and the DNA ligand-based analog to “Western”blotting), surface plasmon resonance (SPR), surface acoustic andtransverse wave (SAW and STW)-based biosensing, plastic-adherent, orradioisotopic, and wherein said assay provides detection in whole blood,plasma, serum, saliva, interstitial fluid, synovial fluid, cerebrospinalfluid, mucus, or urine in tubes, cuvettes or on flat surfaces such asmembranes or plastic or glass arrays.
 11. The DNA ligand sequence ofclaim 10 wherein the target is bone marker consisting of C-telopeptide(CTx; of the common 8 or 26 amino acid length varieties), helicalpeptide (HP), hydroxylysine, N-telopeptide (NTx), Osteocalcin or peptidefragments of Osteocalcin, Pro-Cathepsin K, deoxypyridinoline (DP orDPD), or pyridinoline (Pyd) and said DNA ligand sequence is selectedfrom SEQ ID NOs. 1-238.
 12. The DNA ligand sequence of claim 10 whereinthe target is human growth hormone (hGH or somatotropin) and itsvariants including modified forms of recombinant hGH (rhGH) and said DNAligand sequence is selected from SEQ ID NOs. 325-428.
 13. The DNA ligandsequence of claim 10 wherein the target is metabolite such as D-glucose(dextrose) or creatinine (Cr) from blood or urine and said DNA ligandsequence is selected from SEQ ID NOs. 239-294.
 14. The DNA ligandsequence of claim 10 wherein the target is an interleukin or cytokineand said DNA ligand sequence is selected from SEQ ID NOs. 613-684. 15.The DNA ligand sequence of claim 10 wherein the target is1-hydroxy-vitamin D2, 1-hydroxy-vitamin D3, 25-hydroxy-vitamin D3, orrelated derivative of vitamin D and said DNA ligand sequence is selectedfrom SEQ ID NOs. 429-526.
 16. The DNA ligand sequence of claim 10wherein the target is N-acetylglucosamine (NAG or O-GlcNAc) group addedpost-translationally to a protein or a stem cell and said DNA ligandsequence is selected from SEQ ID NOs. 887-906.
 17. The DNA ligandsequence of claim 1, wherein said nucleic acid sequence is produced bychemical synthesis, wherein said nucleic acid sequence is linear,wherein said nucleic acid sequence has two- or three-dimensional linkedmultiple aptamers or aptamer binding sites in which said aptamer bindingsites have two or more single-stranded segments of 5-10 bases, andwherein intervening nucleotide sequences between said aptamer bindingsites do not bind the target.
 18. The DNA ligand sequence of claim 1,wherein said nucleic acid sequence is produced biosynthetically(enzymatically) by polymerase chain reaction (“PCR”), asymmetric PCR, orother DNA polymerase-based reaction using a complementary template DNA,wherein said nucleic acid sequence is linear, wherein said nucleic acidsequence has two- or three-dimensional linked multiple aptamers oraptamer binding sites in which said aptamer binding sites have two ormore single-stranded segments of 5-10 bases, and wherein interveningnucleotide sequences between said aptamer binding sites do not bind thetarget.
 19. A method for normalizing clinical analyte levels in a urinesample against the creatinine content of urine by comprising: adding acreatinine-specific aptamer beacon to said urine sample, wherein saidcreatinine-specific aptamer opens its structure and fluoresces in linearproportion to the amount of creatinine in urine; and wherein saidcreatinine-specific aptamer is selected from SEQ ID NOs 239-294.
 20. Amethod of enabling aptamer a FRET-aptamer assay from a urine samplecomprising: removing creatinine and urea from said urine sample;collecting the purified target material in the void volume from asize-exclusion chromatography column having a molecular weight cut offof 1,000-5,000 daltons; and running said FRET-aptamer assay.